Thermal conductivity

Thermal Conductivity Theory, Properties, and Applications PHYSICS OF SOLIDS AND LIQUIDS Editorial Board: Jozef T. De...

Author: Terry M. Tritt

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Thermal Conductivity Theory, Properties, and Applications

PHYSICS OF SOLIDS AND LIQUIDS Editorial Board:

Jozef T. Devreese ● University of Antwerp, Belgium Roger P. Evrary ● University of Li`ege, Belgium Stig Lundqvist ● Chalmers University of Technology, Sweden Gerald D. Mahan ● University of Tennessee, USA Norman H. March ● University of Oxford, England

Current Volumes in the Series CRYSTALLINE SEMICONDUCTING MATERIALS AND DEVICES Edited by Paul N. Butcher, Norman H. March, and Mario P. Tosi ELECTRON CORRELATION IN MOLECULES AND CONDENSED PHASES N. H. March ELECTRONIC EXCITATIONS AT METAL SURFACES Ansgar Liebsch EXCITATION ENERGY TRANSFER PROCESSES IN CONDENSED MATTER: Theory and Applications Jai Singh FRACTALS Jens Feder INTERACTION OF ATOMS AND MOLECULES WITH SOLID SURFACES Edited by V. Bortolani, N. H. March, and M. P. Tosi IMPURITY SCATTERING IN METALLIC ALLOYS Joginder Singh Galsin LOCAL DENSITY THEORY OF POLARIZABILITY Gerald D. Mahan and K. R. Subbaswamy MANY-PARTICLE PHYSICS, Third Edition Gerald D. Mahan ORDER AND CHAOS IN NONLINEAR PHYSICAL SYSTEMS Edited by Stig Lundqvist, Norman H. March, and Mario P. Tosi PHYSICS OF LOW-DIMENSIONAL SEMICONDUCTOR STRUCTURES Edited by Paul Butcher, Norman H. March, and Mario P. Tosi QUANTUM TRANSPORT IN SEMICONDUCTORS Edited by David K. Ferry and Carlo Jacoboni THERMAL CONDUCTIVITY: Theory, Properties, and Applications Edited by Terry M. Tritt

A Continuation Order Plan is available for this series. A continuation order will bring delivery of each new volume immediately upon publication. Volumes are billed only upon actual shipment. For further information please contact the publisher.

Thermal Conductivity Theory, Properties, and Applications Edited by

Terry M. Tritt Clemson University Clemson, South Carolina

Kluwer Academic / Plenum Publishers New York, Boston, Dordrecht, London, Moscow

Library of Congress Cataloging-in-Publication Data Thermal conductivity: theory, properties, and applications/[edited by] Terry Tritt. p. cm. — (Physics of solids and liquids) Includes bibliographical references and index. ISBN 0-306-48327-0 1. Thermal conductivity. I. Tritt, Terry M. II. Series. QC176.8.T39T48 2004 536⬘.2012—dc22 2003064141

ISBN 0-306-48327-0 䉷2004, Kluwer Academic / Plenum Publishers, New York 233 Spring Street, New York, New York 10013 http://www.wkap.nl 10

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A C.I.P. record for this book is available from the Library of Congress All rights reserved No part of this book may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, microﬁlming, recording, or otherwise, without written permission from the Publisher, with the exception of any material supplied speciﬁcally for the purpose of being entered and executed on a computer system, for exclusive use by the purchaser of the work. Permissions for books published in Europe: [email protected] Permissions for books published in the United States of America: [email protected] Printed in the United States of America

PREFACE It has been almost thirty years since a book was published that was entirely dedicated to the theory, description, characterization and measurement of the thermal conductivity of solids. For example, the excellent texts by authors such as Berman1 , Tye2 and Carlslaw & Jaeger3 remain as the standards in the ¢eld of thermal conductivity. Tremendous e¡orts were expended in the late 1950’s and 1960’s in relation to the measurement and characterization of the thermal conductivity of solidstate materials. These e¡orts were made by a generation of scientists, who for the most part are no longer active, and this expertise would be lost to us unless we are aware of the great strides they made during their time. I became interested in the ¢eld of thermal conductivity in the mid 1990’s in relation to my own work on the next generation thermoelectric materials, of which the measurement and understanding of thermal conductivity is an integral part.4 In my search for information, I found that most of the books on the subject of thermal conductivity were out of print. Much of the theory previously formulated by researchers such as Klemens5 and Slack6 contain considerable theoretical insight into understanding thermal conductivity in solids. However, the discovery of new materials over the last several years which possess more complicated crystal structures and thus more complicated phonon scattering mechanisms have brought new challenges to the theory and experimental understanding of these new materials. These include: cage structure materials such as skutterudites and clathrates, metallic glasses, quasicrystals as well as many of new nano-materials which exist today. In addition the development of new materials in the form of thin ¢lm and superlattice structures are of great theoretical and technological interest. Subsequently, new measurement techniques (such as the 3-! technique) and analytical models to characterize the thermal conductivity in these novel structures were developed. Thus, with the development of many new and novel solid materials and new measurement techniques, it appeared to be time to produce a more current and readily available reference book on the subject of thermal conductivity. Hopefully, this book, Thermal Conductivity-2004: Theory, Properties and Applications, will serve not only as a testament to those researchers of past generations whose great care in experimental design and thought still stands today but it will also describe many of the new developments over the last several years. In addition, this book will serve as an extensive resource to the next generation researchers in the ¢eld of thermal conductivity. First and foremost, I express great thanks to the authors who contributed to this

VI

PREFACE

book for their hard work and dedication in producing such an excellent collection of chapters. They were very responsive to the many deadlines and requirements and they were a great group of people to work with. I want to personally acknowledge my many conversations with Glen Slack, Julian Goldsmid, George Nolas and Ctirad Uher, as well as many other colleagues in the ¢eld, as I grasped for the knowledge necessary to personally advance in this ¢eld of research. I also want to acknowledge the support and encouragement of my own institution, Clemson University (especially my Chairman : Peter Barnes), during this editorial and manuscript preparation process. I am truly indebted to all my graduate students, for their contributions to these volumes, their hard work, for the patience and understanding they exempli¢ed during the editorial and writing process. A special thanks goes to the publishers and editors at Kluwar Press for their encouragement and patience in all stages of development of these manuscripts for publication. I am indebted to my assistant at Clemson University, Lori McGowan, whose attention to detail and hard work (copying, reading, ¢ling, corresponding with authors, etc.) helped make this book possible. I especially wish to acknowledge my wonderful wife, Penny, and my great kids for their patience and understanding for the many hours that I spent on this work. Terry M. Tritt September 18, 2003 Clemson University Clemson, SC REFERENCES 1. 2. 3. 4. 5. 6.

Thermal Conduction in Solids, R. Berman, Clarendon Press, Oxford, 1976. Thermal Conductivity Vol. I and Vol. II, edited by R. P. Tye, Academic Press, New York, 1969. H. S. Carslaw and J. C. Jaeger, ‘‘Conduction of Heat in Solids’’ (Oxford University Press, Oxford, 1959). ‘‘Recent Ternds in Thermoelectric Materials Research’’ Terry M. Tritt, editor, (Academic Press, Volumes 69^71, Semiconductors and Semimetals, 2002). See for example P. G. Klemens, Chapter 1, p1 of Thermal Conductivity Vol. I, edited by R. P. Tye, Academic Press, New York, 1969. Solid State Physics, G. A. Slack, 34, 1, Academic Press, New York, 1979.

LIST OF SYMBOLS Ch. 1.1 ^ ^ Q ^ T ^ c ^ n ^ rT ^ v ^ @E=@t^ ^ C ^ l ^ k ^ E ^ ^ f0 k ^ EF ^ kB ^ vk e ^ Eef f ^ J ^ ^ Kn ^ ^ Lo ^ D ^ kf qD ^ G’ ^ h ^ m* ^ ^ nc ^ vF ^ ^ We

Yang total thermal conductivity excitation heat £ow rate/ heat £ux vector absolute temperature heat capacity concentration of particles temperature gradient velocity Time rate of change of energy relaxation time total heat capacity particle mean free path electron wave vector electric ¢eld distribution function Fermi energy constant Boltzmann’s constant electron velocity electron charge e¡ective ¢eld elecrical current density general integral electrical conductivity standard Lorentz number Debye temperature for phonons electron wave number at Fermi surface phonon Debye wave number constant representing strength of electron-phonon interaction Planck constant electron e¡ective mass number unit cells per unit volume electron velocity at Fermi surface resistivity electronic thermal resistivity

VIII

LIST OF SYMBOLS

Wi o EG f0 e f0 h EFe EFh Kn Kn0 h !~q

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

constant residual electrical resistivity energy gap equilibrium distribution for electron equilibrium distribution for holes distances of Fermi level below bottom of conduction band distances of Fermi level above top of valence band integral for electrons integral for holes constant holes mobility phonon frequencey

@!~q @q

^ group velocity

q N~q ~ g q L !D ~ B

M V mi fi m d ND r BD C d G r0 Le p

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

wave vector phonon distribution function phonon group velocity phonon scattering relaxation time angle between ~ g and rT lattice thermal conductivity Debye frequency (resonant frequency ?) constant vector-determine s anisotropy of phonon distribution parameter de¢ned in the text (units of time) constant Gru«neisen constant average atomic mass volume per atom mass of atom fraction of atoms with mass mi average mass of all atoms sample size for single crystal or grain size for a polycrystalline sample number dislocation lines per unit area core radius Burgers vector of dislocation constant proportional to concentration of resonant defects electron-phonon interaction constant or deformation potential mass density proportionality constant chemical shift related to splitting of electronic states mean radius of localized state mean free path of electron wavelength of phonon

LIST OF SYMBOLS

Ch. 1.2 e p L

^ ^ ^ ^ ^ ^

Je n v t le m JQ cv cM E D U kB TF NA Z R h k E(k) k Uk H’ ðEÞ S m* A(E) imp Wkk 0 V kTF kF a0 ni q !q

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

IX

Uher total thermal conductivity thermal conductivity of electrons thermal conductivity of phonons electrical conductivity resistivity constant that relates thermal conductivity of pure metals to their electrical conductivity electrical current density number of electrons per unit volume velocity time electrical ¢eld relaxation time/ collision time mean free path between electrons electron mass thermal current density electronic speci¢c heat per unit volume molar speci¢c heat chemical potential/ Fermi level/ Fermi energy (EF ) particular energy state density internal energy of electron Boltzmann constant Fermi temperature Avagardo’s number valence of electron universal gas constant coe⁄cient of linear speci¢c heat of metals#Sommer¢eld constant Planck’s constant Bloch wave vector of an electron Bloch energy of an electron wavefunction internal energy perturbation Hamiltonian varying function of E ? Seebeck coe⁄cient#thermoelectric power Peltier coe⁄cient e¡ective mass vector quantity impurity resistivity collision probability volume Thomas-Fermi screening parameter Fermi wave-vector (momentum) Bohr radius density of impurities wave vector frequency of vibration

X

LIST OF SYMBOLS

!D ^ Debye frequency ^ sample volume V0 k ^ incoming Bloch state k’ ^ outgoing Bloch state G ^ reciprocal lattice vector r ^ point of electron ^ point of lattice ion Ri Heion ^ potential energy of an electron in the ¢eld of all ions of lattice^interaction Hamiltonian ^ unit polarization vectors e“q c ^ speed of sound ^ Debye temperature D s ^ temperature related to longitudinal sound velocity d ^ dimensionality of metallic system Lexp ^ Wiedemann-Franz ratio Wexp ^ total measured electronic thermal resistivity exp ^ electrical resistivity U ^ umklapp electron-electron value of the e¡ectiveness parameter Wep ^ ideal thermal resistivity of metals M ^ mass of an ion ^ coupling constant C2j Ma ^ average atomic mass ^ number of atoms in a primitive cell nc ^ high temperature Gru«neisen constant ^ low temperature heat capacity 0 ND ^ dislocation density B ^ Burgers vector of dislocation TL:T: ^ low temperature domain TH:T: ^ high temperature regime (T = 1) k ^ electron wave vector q ^ phonon small wave vector C ^ constant D ^ constant Ch. 1.3 C v m !D l t k n nD ! G

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

Murashove & White thermal conductivity heat capacity per unit volume average phonon group velocity heat transfer in gases polarization branch Debye cut-o¡ frequency mean free path of phonons relaxation time wave vectors number of atoms Debye cut-o¡ frequency frequency reciprocal lattice vector

LIST OF SYMBOLS

N t d A’ V0 M M D ?? r0 !0 l D E C h kr

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

Ch. 1.4 t E r t0 i -e u f(E) g(E) m* E e g Fn KS m L r i L lt cv

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

phonon concentration time dimension temperature-independent parameter e¡ective volume of defects mass of regular elementary unit of substance di¡erence in mass btw defect and regular unit Debye characteristic temperature static binding energy nearest-neighbor distance characteristic resonant frequency interatomic spacing coe⁄cient depticting strength of host-guest coupling Einstein temperature cut-o¡ frequency refractive index Stefan-Boltzmann constant Rosseland mean absorption coe⁄cient Nolas & Goldsmid relaxation time energy constant constant electric current electronic charge velocity of charge carriers in x direction Fermi distribution function carrier distribution function Fermi energy e¡ective mass of carriers electrical conductivity electric ¢eld Seebeck coe⁄cient electronic thermal conductivity density of states E/KB T Fermi-Dirac integral integrals reduced Fermi energy gamma function mobility of charge characters Lorenz number scattering parameter electric current density lattice contribution to total thermal conductivity mean free path of phonon speci¢c heat per unit volume

XI

XII

v D ! b A B C ci Mi M M N !D L D V T R Tm m NA Am

LIST OF SYMBOLS

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

Ch. 1.5 Z E T ymax y G L Uiso ‘ L

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

Ch. 1.6 JQ B RB K’

^ ^ ^ ^

speed of sound Debye temperature angular frequency of phonons constant constant constant constant concentration of unit cells mass of unit cells average mass per unit cell average atomic mass number of cells per unit volume Debye frequency grain size lattice conductivity average atomic volume Gru«neisen parameter thermal expansion coe⁄cient compressibility density gas constant melting temperature melting energy Avagadro’s number mean atomic weight Nolas thermoelectric ¢gure of merit Seebeck coe⁄cient electrical conductivity thermal conductivity electronic contribution to thermal conductivity temperature maximum ¢lling fraction ¢lling fraction guest ion lattice thermal conductivity mean square displacement average over all directions vacancy ¢tting parameter#represents inelastic scattering length Mahan heat £ow boundary conductance boundary resistance thermal conductivity at zero electric ¢eld

LIST OF SYMBOLS

K ^ thermal conductivity ^ boundary impedence SB ^ boundary impedence KB q ^ phonon mean free path ^ site location Ri ^ site velocity vi ^ frequency ! q ^ wave vector ^ polarization N ^ number unit cells ^ polarization vector ^ mean free path of phonon lp h ^ Planck’s constant T ^ temperature ^ temperature for electrons Te Tp ^ temperature for phonons Ke;p ^ bulk thermal conductivity of electrons and phonons P ^ constant J2 ^ Joule heating ^ length scale r ^ point in time t ^ time vz (q) ^ velocity of phonon (q) ^ lifetime hB (w (q)) ^ Boson occupation function Ch. 1.7 Z E L S

^ ^ ^ ^ ^

Ch. 2.1 L E TOT PSAM LS T A PLOSS PIN T S B

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

Yang and Chen ¢gure of merit total thermal conductivity thermal conductivity of electrons electrical conductivity Seebeck coe⁄cient Tritt & Weston lattice contribution to total thermal conductivity electronic contribution to total thermal conductivity the total thermal conductivity, the power £owing through the sample, the sample length between thermocouples, the temperature di¡erence measured and the cross sectional area of the sample through which the power £ows. the power that is lost (radiation, conduction etc.) is the power input thermopower temperature gradient the Stephan-Boltzman constant S B = 5.7 x 10 8 W/m2 -K4 )

XIII

XIV

LIST OF SYMBOLS

^ TSAM ^ TSURR ^ ^ ^ ^ L0 C ^ I ^ r1 ; r2 ^ D ^ ^ Cp K ^ TPP ^ dQ=dT^ ^ T1 C ^ R ^ K ^ ^ T0 ^ ^ VA VIR ^ VTE ^ ^ QP RC1 ^ ZT ^ Ch. 2.2 ! I0 P Rh T2! ’ C R0 V V1! b p/w dF kF Ts s h flinear KFxy ky

^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^

emissivity the temperature of the sample the temperature of the surroundings the electrical conductivity the electrical conductivity the Lorentz number heat capacity electric current sample radii for the radial £ow method thermal di¡usivity heat capacity thermal conductance temperature gradient peak to peak the time rate of change of heat in the heater the heater temperature the heater heat capacity the heater resistance the sample thermal conductance bath temperature relaxation time adiabatic voltage resistive voltage thermoelectric voltage Peltier Heat Contact Resistance ¢gure of merit Borca-Tasciuc and Chen angular modulation frequency amplitude power resistance amplitude of AC temperature rise phase shift temperature coe⁄cient of resistance heater resistance under no heating conditions voltage amplitude of the voltage applied across the heater half-width of the heater power amplitude dissipated per unit length of the heater ¢lm thickness cross-plane thermal conductivity of the ¢lm temperature rise at the ¢lm-substrate interface thermal di¡usivity of the substrate constant 1 linear function of ln! ratio between the in-plane and cross-plane thermal conductivity cross-plane thermal conductivity

LIST OF SYMBOLS

kx ^ in-plane thermal conductivity ^ heater thickness dh (cÞh ^ heat capacitance Rth ^ thermal boundary resistance T ^ average complex temperature rise L ^ distance from the heater to the heat sink ^ heater temperature rise Th ^ temperature of the sink Ts RMembraam ^ thermal resistance of the membrane RHeater ^ total thermal resistance T(x,t) ^ temperature response of a thin ¢lm membrane ^ thermal di¡usivity along the membrane 2A ^ magnitude of the heat £ux along x Tac ^ AC temperature ^ complex amplitude of the ac temperature rise q ^ amplitude of the heat £ux generated by the heater m ^ (i2!/)1=2 as de¢ned in the text ^ Stefan-Boltzmann constant ^ ambient and heat sink temperature T0 R ^ bridge electrical resistance ^ emissivity P ^ time constant of the bridge ^ cross-section k ^ thermal conductivity r ^ re£ectivity Ch. 3.1 Tc ZT S Z

^ ^ ^ ^ ^ ^ ^

Ch. 3.2 L E TOT T L0 ZT

^ ^ ^ ^ ^ ^ ^ ^ ^

Sun & White thermal conductivity superconducting transition temperature ¢gure of merit Seebeck coe⁄cient electrical conductivity average coordination number mean coordination number Pope and Tritt lattice contribution to total thermal conductivity electronic contribution to total thermal conductivity the total thermal conductivity, thermopower temperature gradient the electrical conductivity the electrical conductivity the Lorentz number [2.45 x 108 (V/K)2 ] ¢gure of merit

XV

XVI

Ch. 3.3

LIST OF SYMBOLS

Savage & Rao

^ electrical conductivity tot ^ total electrical conductivity ^ electron conductivity e ^ hole conductivity h n ^ electron concentration ^ carrier mobility ^ hole mobility h ^ electrical resistivity ^ electrical resistivity due to scattering by phonons L ^ residual electrical resistivity due to scattering by impurities and defects R R ^ electrical resistance ^ electrical resistivity for empty single wall carbon nanotube bundles E ^ electrical resistivity for ¢lled single wall carbon nanotube bundles F k ^ Boltzmann constant e ^ electron charge ^ Fermi energy EF Eg ^ energy gap S ^ thermopower ^ di¡usion thermopower Sd Sg ^ phonon-drag thermopower S tot;met ^ total thermopower in metals S sem ^ thermopower in semiconductors T ^ temperature p ^ hole concentration ^ thermal conductivity C ^ heat capacity ‘ ^ phonon mean free path ^ rate of heat £ux jQ U ^ energy ^ heat capacity at constant pressure Cp ^ heat capacity at constant volume Cv C ph ^ heat capacity contribution due to phonons ^ heat capacity contribution due to electons C el H ^ magnetic ¢eld ZT ^ ¢gure of merit LA ^ longitundinal acoustic

CONTENTS Section 1. ^ Overview of Thermal Conductivity in Solid Materials Chapter 1.1 ^ Theory of Thermal Conductivity (Jihui Yang) Introduction Simple Kinetic Theory Electronic Thermal Conduction Lattice Thermal Conductivity Summary References

1 2 3 9 17 17

Chapter 1.2 ^ Thermal Conductivity of Metals (Ctirad Uher) Introduction Carriers of Heat in Metals The Drude Model Speci¢c Heat of Metals The Boltzmann Equation Transport Coe⁄cients Electrical Conductivity Electrical Thermal Conductivity Scattering Processes Impurity Scattering Electron-Phonon Scattering Electron-Electron Scattering E¡ect of e-e Processes on Electrical Resistivity E¡ect of e-e Processes on Thermal Resistivity Lattice Thermal Conductivity Phonon Thermal Resistivity Limited By Electrons Other Processes Limiting Phonon Thermal Conductivity in Metals Thermal Conductivity of Real Metals Pure Metals Alloys Conclusion References

21 22 24 29 32 35 40 44 46 46 50 61 64 69 73 73 77 79 79 86 87 88

XVIII

CONTENTS

Chapter 1.3 ^ Thermal Conductivity of Insulators and Glasses (Vladimir Murashov and Mary Anne White) Introduction Phononic Thermal Conductivity in Simple, Crystalline Insulators Acoustic Phonons Carry Heat Temperature-Dependence of Impurities More Complex Insulators: The Role of Optic Modes Molecular and Other Complex Systems Optic-Acoustic Coupling Thermal Conductivity of Glasses Comparison with Crystals More Detailed Models The Exception : Recent Amorphous Ice Results Minimum Thermal Conductivity Radiation References

93 94 94 96 97 97 97 99 100 100 100 101 101 102 102

Chapter 1.4 ^ Thermal Conductivity of Semiconductors (G. S. Nolas and H. J. Goldsmid) Introduction Electronic Thermal Conductivity in Semiconductors Transport Coe⁄cients for a Single Band Nondegenerate and Degenerate Approximations Bipolar Conduction Separation of Electronic and Lattice Thermal Conductivities Phonon Scattering in Impure and Imperfect Crystals Pure Crystals Scattering of Phonons by Impurities Boundary Scattering Prediction of the Lattice Thermal Conductivity References

105 106 106 109 110 112 114 114 115 117 118 120

Chapter 1.5 ^ Semiconductors and Thermoelectric Materials (G. S. Nolas, J. Yang, and H. J. Goldsmid) Introduction Established Materials Bismuth Telluride and Its Alloys Bismuth and Bismuth-Antimony Alloys IV-VI Compounds Silicon, Germanium, and Si-Ge Alloys Skutterudites Binary (Un¢lled) Skutterudites E¡ect of Doping on the Co Site Filled Skutterudites Clathrates Half-Heusler Compounds E¡ect of Annealing Isoelectronic Alloying on the M and Ni Sites E¡ect of Grain Size Reduction

123 124 124 126 127 128 129 130 132 133 137 141 142 142 144

CONTENTS

Novel Chalcogenides and Oxides Tl9 GeTe6 Tl2 GeTe5 and Tl2 SnTe5 CsBi4 Te6 NaCo2 O4 Summary References Chapter 1.6 ^ Thermal Conductivity of Superlattices (G. D. Mahan) Introduction Parallel to Layers Perpendicular to Layers Thermal Boundary Resistance Multilayer Interference What is Temperature? Superlattices with Thick Layers ‘‘Non-Kapitzic’’ Heat Flow Analytic Theory Summary References

XIX

145 146 146 147 147 149 149 153 154 154 154 156 157 159 161 162 163 164

Chapter 1.7 ^ Experimental Studies on Thermal Conductivity of Thin Film and Superlattices (Bao Yang and Gang Chen) Introduction 167 Thermal Conductivity of Metallic Thin Films 169 Thermal Conductivity of Dielectric Films 171 171 Amorphous SiO2 Thin Films Thin Film Coatings 173 Diamond Films 174 Multilayer Interference 174 Thermal Conductivity of Semiconductor and Semimetal Thin Films 174 Silicon Thin Films 175 Semimetal Thin Films 177 Semiconductor Superlattices 178 Conclusions 182 Acknowledgments 182 References 182 Section 2 ^ Measurement Techniques Chapter 2.1 ^ Measurement Techniques and Considerations for Determining Thermal Conductivity of Bulk Materials (Terry M. Tritt and David Weston) Introduction Steady State Method (Absolute Method) Overview of Heat Loss and Thermal Contact Issues Heat Loss Terms The Comparative Technique The Radial Flow Method Laser-Flash Di¡usivity

187 188 189 191 193 195 197

XX

CONTENTS

The Pulse-power Method (‘‘Maldonado’’ Technique) Parallel Thermal Conductance Technique Z-Meters or Harman Technique Summary References

Chapter 2.2 ^ Experimental Techniques for Thin^Film Thermal Conductivity Characterization (T. Borca-Tasciuc and G. Chen) Introduction Electrical Heating and Sensing Cross-Plane Thermal Conductivity Measurements of Thin Films The 3! Method Steady-State Method In-Plane Thermal Conductivity Measurements Membrane Method Bridge Method In-Plane Thermal Conductivity Measurement without Substrate Removal Optical Heating Methods Time Domain Pump-and-Probe Methods Frequency^Domain Photothermal and Photoacoustic Methods Photothermal Re£ectance Method Photothermal Emission Method Photothermal Displacement Method Photothermal Defelection Method (Mirage Method) Photoacoustic Method Optical-Electrical Hybrid Methods Summary Acknowledgments References

199 200 201 202 202

205 208 208 208 213 214 216 222 225 225 226 230 230 230 231 231 231 232 233 234 234

Section 3 ^ Thermal Properties and Applications of Emerging Materials Chapter 3.1 - Ceramics and Glasses (Rong Sun and Mary Anne White) Introduction Ceramics Traditional Materials with High Thermal Conductivity Aluminum Nitride (AlN) Silicon Nitride (Si3 N4 ) Alumina (Al2 O3 ) Novel Materials with Various Applications Ceramic Composites Diamond Film on Aluminum Nitride Silicon Carbide Fiber-reinforced Ceramic Matrix Composite (SiC-CMC) Carbon Fiber-incorporated Alumina Ceramics Ceramic Fibers Glass-ceramic Superconductor Other Ceramics

239 239 240 240 243 244 244 244 244 244 245 245 245 246

CONTENTS

Rare-earth Based Ceramics Magnesium Silicon Nitride (MgSiN2 ) Thermoelectric Ceramics Glasses Introduction Chalcogenide Glasses Other Glasses Conclusions References

XXI

246 247 247 248 248 248 249 250 250

Chapter 3.2 ^ Thermal Conductivity of Quasicrystalline Materials (A. L. Pope and Terry M. Tritt) Introduction Contributions to Thermal Conductivity Low-Temperature Thermal Conduction in Quasicrystals Poor Thermal Conduction in Quasicrystals Glasslike Plateau in Quasicrystalline Materials Summary References

255 257 257 258 258 259 259

Chapter 3.3 ^ Thermal Properties of Nanomaterials and Nanocomposites (T. Savage and A. M. Rao) Nanomaterials Carbon Nanotubes Electrical Conductivity, Thermoelectric Power (TEP) Thermal Conductivity, Heat Capacity, C Nanowires Electrical Conductivity Thermoelectric Power Thermal Conductivity and Heat Capacity Nanoparticles Nanocomposites Electrical Conductivity Thermal Conductivity Applications References

262 262 262 265 271 274 276 276 277 278 278 279 279 280 280 282

Index

285

Chapter 1.1

THEORY OF THERMAL CONDUCTIVITY Jihui Yang Materials and Processes Laboratory, GM R&D Center, Warren, MI, USA

1. INTRODUCTION Heat energy can be transmitted through solids via electrical carriers (electrons or holes), lattice waves (phonons), electromagnetic waves, spin waves, or other excitations. In metals electrical carriers carry the majority of the heat, while in insulators lattice waves are the dominant heat transporter. Normally, the total thermal conductivity can be written as a sum of all the components representing various excitations : X ; ð1Þ ¼

where denotes an excitation. The thermal conductivities of solids vary dramatically both in magnitude and temperature dependence from one material to another. This is caused by di¡erences in sample sizes for single crystals or grain sizes for polycrystalline samples, lattice defects or imperfections, dislocations, anharmonicity of the lattice forces, carrier concentrations, interactions between the carriers and the lattice waves, interactions between magnetic ions and the lattice waves, etc. The great variety of processes makes the thermal conductivity an interesting area of study both experimentally and theoretically. Historically thermal conductivity measurement was used as a powerful tool for investigating lattice defects or imperfections in solids. In addition to opportunities for investigating exciting, intriguing physical phenomena, thermal conductivity study is also of great technological interest. Materials with both very high and very low thermal conductivities are technologically important. High-thermal-conductivity materials like diamond or silicon have been extensively studied in part because of their potential applications in thermal management of electronics.18 Low-thermal-conductivity materials like skutterudites, clathrates, half-heuslers,

2

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

chalcogenides, and novel oxides are the focus of the recent quest for high-e⁄ciency thermoelectric materials.934 The aim of this chapter is to review and explain the main mechanisms and models that govern heat conduction in solids. More detailed theoretical treatments can be found elsewhere.3538 Furthermore, only heat conduction by carriers (electrons) and lattice waves (phonons) at low temperatures will be discussed. It is in this temperature region that most of the theoretical models can be compared against experimental results. 2. SIMPLE KINETIC THEORY Thermal conductivity is de¢ned as ¼

! Q ; ~T r

ð2Þ

! where Q is the heat £ow rate (or heat £ux) vector across a unit cross section ! perpendicular to Q and T is the absolute temperature. For the kinetic formulation of thermal conduction in gases, let us assume that c is the heat capacity of each particle and n is the concentration of the particles. In the presence of a temperature ! gradient r T , for a particle to travel with velocity ~ its energy must change at a rate of @E ~T: ¼ c~ r ð3Þ @t The average distance a particle travels before being scattered is , where is the relaxation time. The average total heat £ow rate per unit area summing over all particles is therefore ~ ¼ nch~ ~ T ¼ 1 nc2r ~T: Q ~ ir ð4Þ 3 The brackets in Eq. (4) represent an average over all particles. Combining Eqs. (2) and (4), we have 1 1 ¼ nc2 ¼ Cl; ð5Þ 3 3 where C ¼ nc is the total heat capacity and l ¼ is the particle mean free path. In solids the same derivation can be made for various excitations (electrons, phonons, photons, etc.). Equation (5) can then be generalized to 1X C l ; ð6Þ ¼ 3 where the summation is over all excitations, denoted by . In general, Eq. (6) gives a good phenomenological description of the thermal conductivity, and it is practically very useful for order of magnitude estimates. Like most of the nonequilibrium transport parameters, thermal conductivity cannot be solved exactly. Calculations are usually based on a combination of perturbation theory and the Boltzmann equation, which are the bases for analyzing the microscopic processes that govern the heat conduction by carriers and lattice waves.

Sec. 3

ELECTRONIC THERMAL CONDUCTION

3

3. ELECTRONIC THERMAL CONDUCTION The free electron theory of electron conduction in solids in the ¢rst instance considers each electron as moving in a periodic potential produced by the ions and other electrons without disturbance, and then regards the deviation from the periodicity due to the vibrations of the lattice as a perturbation. The possible values of ~ depend on the periodicity and the size of the crystal. The the electron wave vector k ~ k-space is separated into Brillouin zones. The electron energy Ek~ depends on the form of the potential and is a continuous function of k~ in each zone, but it is discontinuous at the zone boundaries. The values of Ek~ in a zone trace out a ‘‘band’’ of energy values. The distribution function that measures the number of electrons in the state k~ and at the location ~ r is fk~. In equilibrium, the distribution function is fk~0 , given by 1 fk~0 ¼ ; ð7Þ Ek~EF exp kB T þ 1 where EF and kB are the Fermi energy and Boltzmann’s constant, respectively. ~ According to the Boltzmann equation, in the presence of an electrical ¢eld E ~ T , the steady state that represents a balance between and a temperature gradient r the e¡ects of the scattering processes and the external ¢eld and temperature gradient can be described as ! fk~ fk~0 @fk~0 @fk~0 ~T þ e ~ ; ¼ ~ k~ r E ð8Þ ðkÞ @T @Ek~ where ðkÞ, ~ k~, and e are the relaxation time, the electron velocity, and the electron charge, respectively. Taking into account the spatial variation of the Fermi energy and the explicit expression of fk~0 , Eq. (8) can be written in the form !! 0 ~ EF fk~ fk~0 @fk~0 Ek~ EF @fk~ ~ r ~ ¼ ~ k~ rT þ e E : ð9Þ ðkÞ T @Ek~ @Ek~ e ~ EF ~r ~eff ¼ E The e¡ective ¢eld acting on the electrons is E e . Equation (9) can be entered into the expressions for the electrical current density J~ and the £ux of ~: energy Q Z ~ ð10Þ J ¼ e~ k~fk~ dk~

and ~¼ Q

Z

k~fk~ dk~: ðEk~ EF Þ~

If we de¢ne a general integral Kn as Z @f~0 1 ~; Kn ¼ ð~ k~Þ2 ðkÞðEk~ EF Þn k dk 3 @Ek~ then Eqs. (10) and (11) can be written as

ð11Þ

ð12Þ

4

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

~eff e K1r ~T J~ ¼ e2 K0 E T

ð13Þ

~ ¼ eK1 E ~eff 1 K 2~ Q rT ; T

ð14Þ

and

respectively. The electronic thermal conductivity can be found with J~ ¼ 0 such that " # ~ Q 1 K2 e ¼ ¼ K2 1 : ð15Þ ~T T K0 r ~ J ¼0

The electrical conductivity can be derived from Eq. (13) as

¼ e2 K 0 :

ð16Þ

@fk~0

Since @Ek~ is approximately a delta function at the Fermi surface with width kB T , Kn can be evaluated by expansion: i 2 2 2 @ 2 n ðEk~Þ n ðEk~Þ Kn ¼ ðEk~ EF Þ þ k T ðE E Þ ð17Þ þ ::: ~ F Ek~¼EF : B k e2 6 @E 2 e2 Therefore39

and

2 2 k2B T 2 k T K2 ¼ ðEF Þ þ O B EF ; 3 e2

ð18Þ

2 K12 O kB T E F : K0

ð19Þ

Equation (15) through (19) lead to the Wiedemann^Franz law with the standard Lorentz number L0 as L0 ¼

e 2 k2B ¼ : T 3 e2

ð20Þ

The numerical value of L0 is 2.4453108 W-/K2 . This shows that all metals have the same electronic thermal conductivity to electrical conductivity ratio, and this ratio is proportional to the absolute temperature. Furthermore, for strong degenerate electron gases, Eq. (20) is independent of the scattering mechanism and the band structure for the electrons as long as the scatterings are elastic. The Wiedemann^Franz law is generally well obeyed at high-temperatures. In the low^ and intermediate^temperature regions, however, the law fails due to the inelastic scattering of the charge carriers.36; 37; 39 Typically one needs to calculate the relaxation times for the various relevant electron scattering processes and use Eqs. (15) and (16) to determine the electronic thermal conductivity and the electrical conductivity. Over a wide temperature range, scattering of electrons by phonons is a major factor for determining the electrical and electronic thermal conductivities. The resistance due to this type of scattering is called the ideal resistance. The ideal electrical and electronic thermal resistances can be approximately written as36

Sec. 3

ELECTRONIC THERMAL CONDUCTION

5

5 1 T D i ¼ ¼ A J5 i D T and 1 A Wi ¼ ¼ i L 0 T

T D

5

J5

respectively, where

Jn

D T

D T

) ( 3 kF 2 D 2 1 J7 ðD =T Þ 1þ 2 2 ; qD T 2 J5 ðD =T Þ

Z ¼

D =T

xn ex ðex 1Þ2

0

ð21Þ

ð22Þ

dx;

ð23Þ

;

ð24Þ

0

A¼

6 3 hq D ðG Þ2

4e2 ðm Þ2 nc kB D k2F 2F

D is the Debye temperature for phonons (to be discussed below), kF is the electron h is the wave number at the Fermi surface, qD is the phonon Debye wave number, 0 Planck constant, G is the constant representing the strength of the electron^phonon interaction, m is the electron e¡ective mass, nc is the number of unit cells per unit volume, and F is the electron velocity at the Fermi surface. According to Eqs. (21) through (24), at high-temperatures (T >> D Þ AT i ¼ ð25Þ 4D and Wi ¼

A i ¼ : 4D L0 L0 T

ð26Þ

The Wiedemann^Franz law is obeyed ; Wi is a constant. At low temperatures (T << D Þ T i ¼ 124:4Að Þ5 ð27Þ D and Wi ¼ 124:4

A L0 T

T D

3

3 kF 2 / T 2: 2 qD

ð28Þ

In addition to the electron^phonon interaction, the electron-defect interaction contributes to the electrical resistivity and electronic thermal resistivity. One can approximately write the resistivity and electronic thermal resistivity We as (Matthiessen’s Rule) 1 ¼ ¼ 0 þ i ð29Þ and We ¼

1 ¼ W0 þ Wi : e

ð30Þ

6

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

Here; 0 and W0 are the residual electrical resistivity and electronic thermal resistivity, respectively, caused by electron scattering due to impurities and defects, and 0 is independent of temperature. If we assume that all defects scatter electrons elastically, 0 and W0 should be related by the Wiedemann^Franz law: W0 ¼ 0 =L0 T / 1=T :

ð31Þ

At very low temperature, since W0 increases and Wi decreases with decreasing temperature, 1 L0 e ¼ T: ð32Þ W0 0 The electronic thermal conductivity increases linearly with increasing temperature. As temperature increases, Wi becomes relatively more important. If Wi increases to values comparable to that of W0 at su⁄ciently low temperature, then e will pass a maximum, decrease, and eventually attain the high-temperature constant described by Eq. (26). In alloys or metals with a high concentration of defects, W0 and Wi only become comparable at high-temperatures. In this case, there is no maximum in the e , versus, T curve, and e will approach the high-temperature constant monotonically as T increases. Both cases are illustrated in Fig. 1, which shows the lowtemperature thermal conductivity of silver measured by White.40 In Fig. 1, sample (a) is obtained by annealing sample (b). Low, temperature thermal conductivity is therefore dramatically a¡ected by the residual resistance. By combining Eqs. (27) through (31), we have

Thermal conductivity (W/cm-K)

200

150

a) annealed b) not annealed

100

50

0

0

20

40

60

80

100

120

140

T (K) FIGURE 1 Thermal conductivity of two silver samples with (a) very low and (b) moderately high residual resistivities from Ref. 40, showing the profound in£uence of the residual resistivity on the low-temperature thermal conductivity. Sample (a) was obtained by annealing sample (b). Reprinted with permission from IOP Publishing Limited.

Sec. 3

ELECTRONIC THERMAL CONDUCTION

7

1.0

( κe / σT ) / L0

0.8 0.6

ρ0/A = 0

0.4

ρ0/A = 0.0191

ρ0/A = 0.0038 ρ0/A = 0.0957

0.2 0.0 0.0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

T/θD FIGURE 2 Calculated ðe =T Þ=L0 versus T =D curves for variouspvalues of 0 =A, and for monovalent ﬃ metals. The calculations are based on Eq. (33) using ðkF =qD Þ2 ¼ ½32=2 for monovalent metals.

e =T ¼ 0 L0 þ ð T Þ5 f½1 þ A

D

0 D T 5 A þ ðD Þ J5 ð T Þ 3 kF 2 D 2 ð Þ ð T Þ J5 ðTD Þ 2 qD

21 2 J7 ðTD Þg

:

ð33Þ

0 This quantity versus T =D is shown ﬃﬃﬃ in Fig. 2 for various values of A , and for p 2 3 monovalent metals (ðkF =qD Þ ¼ 2=2Þ. Figure 2 shows that the Wiedemann^Franz law holds at very high and very low temperatures except for very pure metals, but e =T underestimates L0 at intermediate temperatures in a manner that strongly depends on the amount of impurity present. It should be stressed that Eqs. (21) and (22) were derived without electron^ phonon umklapp processes, and the strength of the electron^phonon interaction was assumed to be a constant. Close agreement between the model and experimental data should not be expected in most cases. Modi¢cations to the model are discussed elsewhere.37 The discussion so far has been focused on degenerate electron gases (like those in metals). In semiconductors, because of the energy gap EG between the top of the valence band and the bottom of the conduction band and the consequence that the Fermi level lies in the gap, the electron distribution may no longer be degenerate. Also, there may exist positively charged particles, the ‘‘holes,’’ that may also contribute to the transport. In this case, the distribution functions for electrons and holes may be written as Ee þ EFe 0 fe exp ð34Þ kB T

and

fh0

Eh þ EFh exp ; kB T

ð35Þ

where fe0 and fh0 are the equilibrium distribution functions for electrons and holes, respectively, Ee and Eh are the electron and hole energies, respectively, and EFe and EFh are the distances of the Fermi level below the bottom of the conduction band

8

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

and above the top of the valence band, respectively. If one wishes to use the general integral de¢ned in Eq. (12), the conductivities can be written similarly to those in Eqs. (15) and (16): ( ) 0 1 ðK1 þ K1 Þ2 0 e ¼ ðK2 þ K2 Þ ð36Þ 0 T K0 þ K0 and 0

¼ e2 ðK0 þ K0 Þ;

ð37Þ

0

where Kn and Kn denote integrals for electrons and holes, respectively, and the distribution functions for the integrals should be those listed in Eqs. (34) and (35). In general, the ratio e =T is rather complicated to work out. For simplicity, assume that the energy bands are parabolic and the energy dependences of the carriers’ relaxation times are the same such that e;h ðEÞ / E ;

ð38Þ

where is a constant, and the subscripts e and h denote the electrons and holes. With some algebra one ¢nds36 # 2 " e kB 5 EG 2 ne e nh h ¼ þ þ 5 þ 2 þ : ð39Þ T e 2 kB T ðne e þ nh h Þ2 In Eq. (39), n and are the carrier concentration and mobility, and again the subscripts e and h denote electrons and holes. The ¢rst term in Eq. (39) is the standard Lorentz number for nondegenerate Fermi distributions. When carrieracoustic phonon scattering dominates, ¼ 1=2; and if ne ¼ nh , Eq. (39) can be written as # 2 " kB EG 2 e =h e ¼ T 2þ 4þ : ð40Þ e kB T ð1 þ e =h Þ2 The second term in Eq. (39) or (40) is called the bipolar di¡usion term. This type of energy transport in addition to that carried by the electrons and the holes is due to the creation of electron^hole pairs that extract an amount of energy EG at the hightemperature end; on recombination this energy is given up to the cold end. The bipolar di¡usion may be a noticeable contribution to the electronic thermal conductivity when both the carrier concentration and the mobility are about equal for electrons and holes, and their mobilities have reasonably high values.41; 42 This should be the case for intrinsic semiconductors. In the case of doped semiconductors only one of the carriers has high mobility; the low-mobility carrier will not be fast enough to accompany the high-mobility carrier for the recombination at the cold end; therefore, the bipolar contribution may not be noticeable. Anomalously, high thermal conductivity at high-temperatures for InSb, Ge, Si, and Bi may be explained by this bipolar di¡usion.43; 44; 45 Figure 3 shows the temperature dependence of ðW WI Þ=T for pure Ge measured by Glassbrenner and Slack.44 The thermal resistance due to isotopes WI is almost independent of temperature and is subtracted from the total thermal resistance W . The term ðW WI Þ=T increases linearly as a function of T for T < 700 K, reaches a maximum at about 700 K, and decreases with increasing T for T >

Sec. 3

ELECTRONIC THERMAL CONDUCTION

9

FIGURE 3 The temperature dependence of ðW WI Þ=T for pure Ge from Ref. 44. W is the total measured thermal resistivity, and WI is the calculated thermal resistance due to isotopes. The dashed line is a theoretical extrapolation for thermal resistivity induced by phonon^phonon interactions.

700 K. The theoretical extrapolation (dashed line) represents T and T 2 components of the thermal resistivity due to phonon^phonon interactions. The former is due to three-phonon umklapp processes (to be discussed), and the latter is attributed to four-phonon processes.46 Deviation from the dashed line at high-temperatures is ascribed to the electronic thermal resistance. It was found that the contribution to the total thermal conductivity from the ¢rst term of Eq. (40) is less than 10% up to the melting point. The majority of the deviation between ðW WI Þ=T and the dashed line at high-temperatures is due to dipolar di¡usion. The values of EG can be estimated by subtracting the lattice component and the ¢rst term of Eq. (40) from the total thermal conductivity and comparing it against the second term in Eq. (40). The results are in agreement with the published results.44 3.1. Lattice Thermal Conductivity Lattice thermal conduction is the dominant thermal conduction mechanism in nonmetals, if not the only one. Even in some semiconductors and alloys, it dominates a wide temperature range. In solids atoms vibrate about their equilibrium positions (crystal lattice). The vibrations of atoms are not independent of each other, but are rather strongly coupled with neighboring atoms. The crystal lattice vibration can be characterized by the normal modes, or standing waves. The quanta of the crystal vibrational ¢eld are referred to as ‘‘phonons.’’ In the presence of a temperature gradient, the thermal energy is considered as propagating by means of wave packets consisting of various normal modes, or phonons. Derivation of phonon dispersion curves (!~q versus q curves, where !~q and q are the phonon frequency and wave

10

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

(a)

(b)

ω* T

optical

ω* T acoustic

acoustic 0

π/a0

T

0

π/a0

T

FIGURE 4 Schematic phonon dispersion curves for a given direction of ~ q of (a) monatomic lattice and (b) diatomic lattice. The lattice parameter is denoted a0 .

vector, respectively) can be found in a standard solid-state physics book.47 Schematic phonon dispersion curves for monatomic and diatomic lattices are shown in Fig. 4. Phonon dispersion curves for solids normally consist of acoustic and optical branches. The low-frequency acoustic branches correspond to atoms in a unit cell moving in same phase, whereas the high-frequency optical branches represent atoms in a unit cell moving in opposite phases. Normally optical phonons themselves are not e¡ective in transporting heat energy because of their small group velocity @!~q=@q, but they may a¡ect the heat conduction by interacting with the acoustic phonons that are the main heat conductors. The phonon distribution function, which represents the average number of phonons with wave vector ~ q, is N~q. In equilibrium, the phonon distribution function can be written as 1 N~q0 ¼ : ð41Þ exp h !~q=kB T 1 The Boltzmann equation assumes that the scattering processes tend to restore a phonon distribution N~q to its equilibrium form N~q0 at a rate proportional to the departure of the distribution from equilibrium, such that N~q N~q0 q

~TÞ ¼ ð~ g r

@N~q0 @T

;

ð42Þ

where ~ g is the phonon group velocity and q is the phonon scattering relaxation time. The heat £ux due to a phonon mode ~ q is the product of the average phonon energy and the group velocity. Therefore the total heat £ux carried by all phonon modes can be written as X ~¼ N~q h!~q~ ð43Þ g : Q ~ q

Substituting Eq. (42) into Eq. (43) yields X X @N~q0 @N~q0 ~¼ ~T ¼ 1 ~T; h!~q2g hcos2 i q Q r h!~q2g q r @T 3 ~q @T ~ q ~ T ; the lattice thermal conductivity is where is the angle between ~ g and r

ð44Þ

Sec. 3

ELECTRONIC THERMAL CONDUCTION

L ¼

~ @N~q0 Q 1X ¼ h!~q2g q : ~T 3 @T r ~ q

11

ð45Þ

At this point approximations need to be made to Eq. (45) in order to obtain meaningful results. Furthermore, evaluations of various phonon scattering relaxation times are usually di⁄cult to make precise. It is not worthwhile to try to calculate Eq. (45) for the precise phonon frequency spectrum and dispersion curve of a real solid. Assumptions of Debye theory should be used: an average phonon velocity (approximately equal to the velocity of sound in solids) is used to replace g , !~q ¼ g for all the phonon branches, and the phonon velocities are the same for all polarizations. The summation in Eq. (45) can be replaced by the integral Z @N~q0 1 L ¼ h!~q2g q fðqÞd~ q; ð46Þ 3 @T where fðqÞd~ q ¼ ð3q2 =22 Þ dq, and therefore fð!Þd! ¼ ð3!2 =22 3 Þ d!. Using the Debye assumptions and Eqs. (41) and (45) leads to Z !D ð h! kB T 2 Þ expð h!=kB T Þ 1 3 L ¼ 2 h! q ð!Þ d!; ð47Þ 2 0 ½expð h!=kB T Þ 12 where !D is the Debye frequency such that Z !D fð!Þd! 3N ¼

ð48Þ

0

is the total number of all distinguishable phonon modes. If we make the substitution x ¼ h!=kB T and de¢ne the Debye temperature D ¼ h!D =kB , Eq. (47) becomes Z D =T kB kB x4 ex L ¼ 2 ð Þ3 T 3 q ðxÞ dx: ð49Þ 2 h ðex 1Þ2 0 Within the Debye approximation the di¡erential lattice speci¢c heat is CðxÞdx ¼

3kB kB 3 3 x4 ex ð Þ T dx: 22 3 h ðex 1Þ2

ð50Þ

If we de¢ne the mean free path of the phonons as lðxÞ ¼ q ðxÞ, the lattice thermal conductivity can be written as Z Z 1 D =T 2 1 D =T L ¼ q ðxÞCðxÞdx ¼ CðxÞlðxÞdx: ð51Þ 3 0 3 0 This is analogous to the thermal conductivity formula [Eq. (6)] derived from simple kinetic theory. Equation (49) is usually called the Debye approximation for the lattice thermal conductivity. If one can calculate the relaxation times i ðxÞ for various phonon scattering processes in solids and add the scattering rates such that X i1 ðxÞ; ð52Þ q1 ðxÞ ¼ i

12

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

Eq. (49) should be su⁄cient to obtain the lattice thermal conductivity. It is indeed then adequate for analyzing and predicting a lot of the experimental data especially when a large concentration of lattice defects prevails in the solid. Sometimes, than even in the case of some chemically pure crystals, because of the existence of appreciable amounts of isotopes, the lattice thermal conductivity can be represented satisfactorily by the Debye approximation. The phonon scattering processes included in the Debye approximate are resistive and are called umklapp processes or U-processes. The total crystal momentum is not conserved for U-processes. Because such processes tend to restore non-equilibrium phonon distribution to the equilibrium distribution described by Eq. (42), they give rise to thermal resistance. There exist, however, other nonresistive and total crystal-momentum-conserving processes that do not contribute to the thermal resistance but may still have profound in£uence on the lattice thermal conductivity of solids. Such processes are called normal processes or N-processes. Even though N-processes themselves do not contribute to thermal resistance directly, they have the great e¡ect of transferring energy between di¡erent phonon modes, thus preventing large deviations from the equilibrium distribution. Since the N-processes themselves do not tend to restore the phonon equilibrium distribution, they cannot be simply added to Eq. (52). The Callaway model is the most widely used in analyzing the e¡ect of N-processes on the lattice thermal conductivity.48 Callaway’s model assumes that N-processes tend to restore a nonequilibrium phonon distribution to a displaced phonon distribution of the form49 ~ expð ~ 1 q h! =kB T Þ ~Þ ¼ N~qð ¼ N~q0 þ ; ð53Þ ~ kB T ½expðh!=kB T Þ 12 exp½( h! ~q Þ=:kB T 1 ~ is some constant vector (in the direction of the temperature gradient) that where determines the anisotropy of the phonon distribution and the total phonon momentum. If the relaxation time for the N-processes is N , Eq. (42) can be modi¢ed to ~Þ N~q N~q0 N~q N~qð @N 0 ~ T Þ ~q : þ ¼ ð~ r ð54Þ q N @T If we de¢ne a combined relaxation time c by c1 ¼ q1 þ N1 ;

ð55Þ

n1 ¼ N~q N~q0 ;

ð56Þ

and de¢ne

the Boltzmann equation [Eq. (54)] can be written as ~ ~ h! expð h!=kB T Þ q expð h!=kB TÞ n1 ~TÞ ð~ r þ ¼ 0: 2 2 2 kB T N kB T ½expð c ½expð h !=kB T Þ 1 h!=kB T Þ 1

ð57Þ

If we express n1 as n1 ¼ q

! h expð h!=kB T Þ ð~ ~ rT Þ ; 2 kB T ½expð h!=kB T Þ 12

then Eq. (57) can be simpli¢ed to

ð58Þ

Sec. 3

ELECTRONIC THERMAL CONDUCTION

~ ~ !q ~ h q h! ~ ~ ~ rT þ ¼ rT : c T N T

13

ð59Þ

~ is in the direction of the temperature gradient, it is convenient to de¢ne a Since parameter with the same dimension as the relaxation time: h 2~ ~¼ rT : ð60Þ T Because ~ q¼~ ! 2 , Eq. (59) can be further simpli¢ed to q ¼ c ð1 þ =N Þ:

ð61Þ

From Eq. (58) it is straightforward [the same procedure as Eqs. (42) through (49)] to show that the lattice thermal conductivity can be expressed as Z D =T kB k B x4 ex L ¼ 2 ð Þ3 T 3 q ðxÞ dx 2 h ðex 1Þ2 0 ¼

k B kB 3 3 ð Þ T 22 h

Z 0

D =T

c ðxÞð1 þ

x4 ex Þ dx: N ðxÞ ðex 1Þ2

ð62Þ

The task now is to determine . Because the total crystal momentum is conserved for the N-processes, the rate of phonon momentum change is zero. Therefore ~ Z N~q N~q ~ qd~ q ¼ 0: ð63Þ N Substituting Eqs. (53) and (58) into Eq. (63), we have Z ~ ~ expð h!=kB T Þ h! q q ~TÞ þ ~ ½ ð~ r d~ q ¼ 0: q 2 k T2 T k B N ½expðh !=kB T Þ 1 B This can be further simpli¢ed by using Eqs. (60) and (61), so that Z expð h!=kB T Þ h! ! ~ T Þðq Þ ~ ð~ r d~ q ¼ 0: 2 k T2 2 N ½expð h !=kB T Þ 1 B

ð64Þ

ð65Þ

By inserting Eq. (63) into Eq. (65) and using the dimensionless x as de¢ned earlier, we can solve for : ,Z Z D =T D =T c ex x4 c ex x 4 ¼ dx dx: ð66Þ 2 N ðex 1Þ N q ðex 1Þ2 0 0 Therefore the lattice thermal conductivity can be written as L ¼ 1 þ 2 ; where

and

Z kB kB 3 3 D =T x4 ex 1 ¼ 2 T c dx 2 h ðex 1Þ2 0

ð67Þ

ð67aÞ

14

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

R D =T kB kB 3 3 ð 0 2 ¼ 2 T R =T D 2 h 0

c x4 ex N ðex 1Þ2

dxÞ2

c x 4 ex N q ðex 1Þ2

dx

:

ð67bÞ

When the impurity level is signi¢cant and all phonon modes are strongly scattered by the resistive processes in a solid, then N >> q and c q . Under this circumstance 1 >> 2 and L is given by Eq. (67a), the same as Eq. (49) since the Nprocesses do not exist. In the opposite extreme, when N-processes are the only phonon scattering processes, we have N << q and c N . The denominator of 2 then approaches 0, leading to in¢nite lattice thermal conductivity as expected because the N-processes do not give rise to thermal resistance. Now that we have derived the formula for the lattice thermal conductivity, the problem is to calculate the relaxation times. Phonon scatterings have been treated by numerous authors. Here we list the main conclusions. For phonon^phonon normal scattering the relaxation rate N1 ¼ B!a T b

ð68Þ

is the general form suggested by best ¢ts to experimental thermal conductivity data; B is a constant independent of ! and T , (a, b) = (1,3) was recommended for LiF and diamond50;51 , and (a, b) = (1, 4) and (2, 3) were used for some group IV and III^V semiconductors.8 Peierls suggested the form U1 / T n expðD =mT Þ

ð69Þ

for the phonon^phonon umklapp scattering with constants n and m on the order of omann model,53 Slack et al. proposed the 1.52 Based on the Leibfried and Schl€ following form for the Gr€ uneisen constant and the average atomic mass of M in the crystal: 54 U1

2 h !2 T expðD =3T Þ: M2 D

ð70Þ

Other empirical n and m values were also used,50;5557 all of which were based again on best ¢ts to experimental data. At su⁄ciently high-temperatures L / 1=T if phonon^phonon umklapp scattering is the dominant process. Klemens was the ¢rst to calculate the relaxation rate for phonon^point-defect scattering where the linear dimensions of the defects are much smaller than the phonon wavelength.58 The corresponding phonon^point-defect scattering rate is X m mi 2 V P1D ¼ !4 fi ð ð71Þ Þ; 3 4 m i where V is the volume per atom, mi is the mass of an atom, fi is the fraction of is the average mass of all atoms. A strain ¢eld modatoms with mass mi; and m i¢cation to Eq. (71) has been described by Abeles.59 The phonon-boundary scattering rate is independent of phonon frequency and temperature and can be written as B1 ¼ =d;

Sec. 3

ELECTRONIC THERMAL CONDUCTION

15

where d is the sample size for a single crystal or the grain size for a polycrystalline sample. For phonon-dislocation scattering, Nabarro separated the e¡ects of the core from the surrounding strain ¢eld.60 The corresponding relaxation rates are r4 3 ! 2

ð72Þ

2 B2D ! ; 2

ð73Þ

1 / ND Core

and 1 / ND Str

where ND is the number of dislocation lines per unit area, r is the core radius, and BD is the Burgers vector of the dislocation. Pohl suggested an empirical nonmagnetic phonon-resonance scattering relaxation rate of 1 ¼ Res

C!2 ð!2 !20 Þ2

;

ð74Þ

where C is a constant proportional to the concentration of the resonant defects and !0 is the resonance frequency.61 This formula accounted well for the observed lowtemperature dip in the thermal conductivity of KNO2 -containing KCl crystals. It has also been used for ¢tting experimental data for clathrates and skutterudites.22;23 According to Ziman, the relaxation time for the scattering of phonons by electrons in the conduction state is given by62 ! e2 ðm Þ3 kB T 1 EP C ¼ 1 2 4 h4 d 2m (

) 1 þ exp½ð12 m 2 EF Þ=kB T þ h2 !2 =8m 2 kB T þ h!=2kB T ! h ln ; kB T 1 þ exp½ð12 m 2 EF Þ=kB T þ h2 !2 =8m 2 kB T h!=2kB T

ð75Þ

where " is the electron^phonon interaction constant or deformation potential and d is the mass density. The relaxation time for scattering of phonons by electrons in a bound state, as given by Gri⁄n and Carruthers,63 is 1 EP B ¼

G!4 ½!2

1 2 2

ð4= hÞ ½1 þ

r20 !2 =42 8

;

ð76Þ

where G is a proportionality constant containing the number of scattering centers, is the chemical shift related to the splitting of electronic states, and r0 is the mean radius of the localized state. It should be pointed out that these formulas for electron^phonon interaction are based on the adiabatic principle and perturbation theory. As argued by Ziman,36 the theory is only valid if the mean free path of electrons Le satis¢es the condition 1 < qLe :

ð77Þ

Since the phonon wave vector q ¼ 2=p , this means that the wavelength of a phonon p must not be longer than the mean free path of the electron it scatters. The model originally developed by Pippard for explaining the ultrasonic attenua-

16

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

tion in metals is, however, applicable over the entire range of qLe .64 Pippard’s relaxation times are 1 ¼ EP

4nm F Le !2 15d2

for

qLe << 1

ð78Þ

and 1 EP ¼

nm F ! 6d

qLe >> 1

for

ð79Þ

where n is the electron concentration and F is the Fermi velocity. There have been several cases in which Pippard’s theory was applied to lattice thermal conductivity.21;65;66 Typically it is necessary to use the full Callaway model [Eqs. (67), (67a), and (67b)] to interpret experimental data on the e¡ect of isotopes when one starts with an isotopically pure crystal. The addition of a small amount of defects will rapidly suppress 2 , which becomes negligible for an impure sample. The decrease of 1 upon increasing defect concentration is much slower. For samples with an appreciable amount of defects (even isotopic defects) it is su⁄cient to use the Debye approximation [Eq. (49)] for examining the low-temperature lattice thermal conductivity. The measured thermal conductivity versus temperature curve is usually ¢t by trial and error for one sample, where an appropriate relaxation rate is carefully chosen for each scattering mechanism believed to be present. The same curves for samples with additional defects are then ¢t by using suitable relaxation rates to re£ect scattering by additional defects. Much interesting physics has been revealed by this method. Di¡erent phonon scattering processes usually dominate in di¡erent temperature ranges. Figure 5 plots the lattice thermal conductivity of a binary 1000 Umklapp Boundary + Point-defect

100

κL (W/m-K)

Boundary

10

1

1

10

100

1000

T (K) FIGURE 5 The lattice thermal conductivity versus temperature of a CoSb3 sample from Ref. 21. The dots and the solid line represent the experimental data and the theoretical ¢t. The dashed curves are the theoretical limits imposed on the phonon heat transport by boundary scatterings, by a combination of boundary plus point-defect scatterings, and by umklapp scatterings.

Sec. 5

REFERENCES

17

skutterudite compound CoSb3 .16 The dots and the solid line represent experimental data and a theoretical ¢t using the Debye approximation, respectively. The possible phonon scattering mechanisms are phonon-boundary, phonon-point defect, and phonon^phonon umklapp scatterings. The dashed lines in Fig. 5 correspond to the theoretical limits on the lattice thermal conductivity set by boundary scattering, a combination of boundary plus point-defect scattering, and umklapp scattering. At high-temperatures (close to D ¼ 300 K), umklapp is the dominant phonon scattering mechanism, while boundary and point-defect scattering dominate at low and intermediate temperatures, respectively. In practice, the dominant phonon method works quite well in predicting the e¡ect of phonon scattering processes. The dominant phonon method assumes that at a given temperature all phonons are concentrated about a particular domih. An empirical power law can then be deduced as nant frequency !dom kB T = follows. If one particular defect can be described by 1= / !a or, equivalently, by 1= / xa T a , taking C / T 3 (for low T Þ and employing the simple kinetic formula [Eq. (5)] yields L / T 3a . Even though the dominant phonon method is not mathematically justi¢ed, the power law is usually valid at low temperatures. For example, one should have L / T 3 at low temperatures if boundary scattering is the dominant phonon scattering mechanism. 4. SUMMARY In this chapter theoretical treatments of the electronic and the lattice thermal conductivities at low temperatures have been reviewed. The electronic thermal resistance for degenerate electron gases is the sum of residual and ideal components. At low temperatures We AT þ B=T 2 , where A and B are constants, while at hightemperatures We approaches a constant. Except for very pure metals, the Wiedemann^Franz law holds well at low and high-temperatures with standard Lorenz number L0 . For intermediate temperatures, the Wiedemann^Franz law breaks down in a way strongly dependent on the amount of the impurity. For intrinsic semiconductors, the bipolar di¡usion process enhances the electronic thermal conductivity. The N- and U-processes are both important for analyzing and predicting the lattice thermal conductivity of solids. The lattice thermal conductivity for isotopically pure crystals can be well described by the full Callaway model. When impurity concentrations are appreciable, the Debye approximation is adequate for modeling experimental data. The di¡erent resistive phonon scattering processes in the Debye approximation dominate in di¡erent temperature ranges. At low temperatures, the power law predicted by the dominant phonon method is often useful in identifying the characteristics of the phonon scattering processes. 5. REFERENCES 1.

2. 3.

D. G. Onn, A. Witek, Y. Z. Qiu, T. R. Anthony, and W. F. Banholzer Some Aspects of the Thermal Conductivity of Isotopically Enriched Diamond Single Crystals Phys. Rev. Lett. 68, 2806^ 2809 (1992). T. R. Anthony, W. F. Banholzer, J. F. Fleischer, L. Wei, P. K. Kuo, R. L. Thomas, and R. W. Pryor Thermal Di¡usivity of Isotopically Enriched 12 C Diamond Phys. Rev. B 42, 1104-1111 (1990). J. R. Olson, R. O. Pohl, J. W. Vandersande, A. Zoltan, T. R. Anthony, and W. F. Banholzer

18

4. 5. 6. 7.

8. 9. 10. 11.

12. 13.

14.

15.

16. 17. 18. 19.

20.

21.

22.

23. 24.

25. 26. 27.

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

Thermal Conductivity of Diamond between 170 and 1200 K and the Isotope E¡ect Phys. Rev B 47, 14850-14856 (1993). L. Wei, P. K. Kuo, R. L. Thomas, T. R. Anthony, and W. F. Banholzer Thermal Conductivity of Isotopically Modi¢ed Single Crystal Diamond Phys. Rev. Lett. 70, 3764-3767 (1993). K. C. Hass, M. A. Tamor, T. R. Anthony, and W. F. Banholzer Lattice Dynamics and Raman Spectra of Isotopically Mixed Diamond Phys. Rev. B 45, 7171-7182 (1992). R. Berman Thermal Conductivity of Isotopically Enriched Diamonds Phys. Rev B 45, 5726-5728 (1992). T. Ruf, W. Henn, M. Asen-Palmer, E. Gmelin, M. Cardona, H.-J. Pohl, G. G. Devyatych, and P. G. Sennikov Thermal Conductivity of Isotopically Enriched Silicon Solid State Commun. 115, 243 (2000). D. T. Morelli, J. P. Heremans, and G. A. Slack Estimation of the Isotope E¡ect on the Lattice Thermal Conductivity of Group IV and Group III-V Semiconductors Phys. Rev B 66, 195 304 (2002). T. M. Tritt, ed., Semiconductors and Semimetals, Vol. 69-71 (Academic Press, San Diego, CA, 2000). D. T. Morelli and G. P. Meisner Low Temperature Properties of the Filled Skutterudite CeFe4 Sb12 J. Appl. Phys. 77, 3777-3781 (1995). J.-P. Fleurial, A. Borshchevsky, T. Caillat, D. T. Morelli, and G. P. Meisner High Figure of Merit in Ce-Filled Skutterudites Proc. 16th Intl. Conf. on Thermoelectrics, (IEEE, Piscataway, NJ, 1996), p. 91-95. B. C. Sales, D. Mandrus, and R. K. Williams Filled Skutterudite Antimonides: A New Class of Thermoelectric Materials Science 272, 1325-1328 (1996). T. M. Tritt, G. S. Nolas, G. A. Slack, A. C. Ehrlich, D. J. Gillespie, and J. L. Cohn LowTemperature Transport Properties of the Filled and Un¢lled IrSb3 Skutterudite System J. Appl. Phys. 79, 8412-8418 (1996). G. S. Nolas, G. A. Slack, D. T. Morelli, T. M. Tritt, and A. C. Ehrlich The E¡ect of RareEarth Filling on the Lattice Thermal Conductivity of Skutterudites J. Appl. Phys. 79, 4002-4008 (1996). G. P. Meisner, D. T. Morelli, S. Hu, J. Yang, and C. Uher Structure and Lattice Thermal Conductivity of Fractionally Filled Skutterudites: Solid Solutions of Fully Filled and Un¢lled End Members Phys. Rev. Lett. 80, 3551-3554 (1998). J. Yang, G. P. Meisner, D. T. Morelli, and C. Uher Iron Valence in Skutterudites: Transport and Magnetic Properties of Co1 x Fex Sb3 Phys. Rev. B 63, 014410 (2000). G. S. Nolas, M. Kaeser, R. T. Littleton IV, and T. M. Tritt High Figure of Merit in Partially Filled Ytterbium Skutterudite Materials Appl. Phys. Lett. 77, 1855-1857 (2000). B. C. Sales, B. C. Chakoumakos, and D. Mandrus Thermoelectric Properties of Thallium-Filled Skutterudites Phys. Rev. B 61, 2475-2481 (2000). L. D. Chen, T. Kawahara, X. F. Tang, T. Hirai, J. S. Dyck, W. Chen, and C. Uher Anomalous Barium Filling Fraction and n-type Thermoelectric Performance of Bay Co4 Sb12 J. Appl. Phys. 90, 1864-1868 (2001). G. A. Lamberton, Jr., S. Bhattacharya, R. T. Littleton IV, M. A. Kaeser, R. H. Tedstrom, T. M. Tritt, J. Yang, and G. S. Nolas High Figure of Merit in Eu-¢lled CoSb3 -based Skutterudites Appl. Phys. Lett. 80, 598-600 (2002). J. Yang, D. T. Morelli, G. P. Meisner, W. Chen, J. S. Dyck, and C. Uher In£uence of ElectronPhonon Interaction on the Lattice Thermal Conductivity of Co1 x Nix Sb3 Phys. Rev. B 65, 094115 (2002). J. Yang, D. T. Morelli, G. P. Meisner, W. Chen, J. S. Dyck, and C. Uher E¡ect of Sn Substituting Sb on the Low Temperature Transport Properties of Ytterbium-Filled Skutterudites, Phys. Rev. B 67, 165207 (2003) J. L. Cohn, G. S. Nolas, V. Fessatidis, T. M. Metcalf, and G. A. Slack Glasslike Heat Conduction in High-Mobility Crystalline Semiconductors Phys. Rev. Lett. 82, 779-782 (1999). J. S. Tse, K. Uehara, R. Rousseau, A. Ker, C. I. Ratcliffe, M. A. White, and G. Mackay Structural Principles and Amorphouslike Thermal Conductivity of Na-Doped Si Clathrates Phys. Rev. Lett. 85, 114-117 (2000). G. S. Nolas and G. A. Slack Thermoelectric Clathrates Am. Sci. 89, 136-141 (2001). J. Dong, O. F. Sankey, and W. Myles Theoretical Study of the Lattice Thermal Conductivity in Ge Framework Semiconductors Phys. Rev. Lett. 86, 2361-2364 (2001). B. C. Sales, B. C. Chakoumakos, R. Jin, J. R. Thompson, and D. Mandrus Structural, Magnetic,

Sec. 5

28.

29. 30.

31.

32. 33.

34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51.

52. 53. 54. 55. 56.

REFERENCES

19

Thermal, and Transport Properties of X8 Ga16 Ge30 (X = Eu, Sr, Ba) Single Crystals Phys. Rev. B 63, 245113 (2001). B. A. Cook, G. P. Meisner, J. Yang, and C. Uher High Temperature Thermoelectric Properties of MNiSn (M=Zr, Hf) Proc. 18th Intl. Conf. on Thermoelectrics, (IEEE, Piscataway, NJ, 1999), pp. 64-67. C. Uher, J. Yang, S. Hu, D. T. Morelli, and G. P. Meisner Transport Properties of Pure and Doped MNiSn (M=Zr, Hf) Phys. Rev. B 59, 8615-8621 (1999). Q. Shen, L. Chen, T. Goto, T. Hirai, J. Yang, G. P. Meisner and C. Uher E¡ects of Partial Substitution of Ni by Pd on the Thermoelectric Properties of ZrNiSn-Based Half-Heusler Compounds Appl. Phys. Lett. 79, 4165-4167 (2001). S. Bhattacharya, Y. Xia, V. Ponnambalam, S. J. Poon, N. Thadani, and T. M. Tritt Reductions in the Lattice Thermal Conductivity of Ball-Milled and Shock Compacted TiNiSn1 x Sbx Half-Heusler Alloys Mat. Res. Soc. Symp. Proc. 691, G7.1 (2002). I. Terasaki, I. Tsukada, Y. Iguchi Impurity-Induced Transition and Impurity-Enhanced Thermopower in the Thermoelectric Oxide NaCo2 x Cux O4 Phys. Rev. B 65, 195106 (2002). I. Terasaki, Y. Ishii, D. Tanaka, K. Takahata and Y. Iguchi Thermoelectric Properties of NaCo2 x Cux O4 Improved by the Substitution of Cu for Co Japanese J. Appl. Phys, Lett., 40, L657 (2001). R. Funahashi and M. Shikano Bi2 Sr2 Co2 Oy Whiskers with High Thermoelectric Figure of Merit Appl. Phys. Lett. 81, 1459-1461 (2002). P. G. Klemens Thermal Conductivity and Lattice Vibrational Modes, in Solid State Physics, Vol. 7, edited by F. Seitz and D. Turnbull, (Academic Press, New York, 1958), pp. 1-98. J. M. Ziman Electrons and Phonons (Clarendon Press, Oxford, UK, 1960). R. Berman Thermal Conduction in Solids (Clarendon Press, Oxford, UK, 1976). G. A. Slack The Thermal Conductivity of Nonmetallic Crystals, in Solid State Physics, Vol. 34, edited by H. Ehrenreich, F. Seitz, and D. Turnbull (Academic Press, New York, 1979), pp. 1-71. N. W. Ashcroft and N. D. Mermin, Solid State Physics (Saunders, Philadelphia, 1976). G. K. White Thermal Conductivity of Silver at Low Temperatures Proc. Phys. Soc. London A66, 844-845 (1953). P. J. Price Ambipolar Thermodi¡usion of Electrons and Holes in Semiconductors Phil. Mag. 46, 12521260 (1955). J. R. Drabble and H. J. Goldsmid, Thermal Conduction in Semiconductors (Pergamon Press, Oxford, UK, 1961). G. Busch and M. Schneider Heat Conduction in Semiconductors Physica 20, 1084-1086 (1954). C. J. Glassbrenner and G. A. Slack Thermal Conductivity of Silicon and Germanium from 3 K to the Melting Point Phys. Rev 134, A1058-A1069 (1964). C. Uher and H. J. Goldsmid Separation of the Electronic and Lattice Thermal Conductivities in Bismuth Crystals Phys. Stat. Sol. (b) 65, 765-772 (1974). I. Pomeranchuk On the Thermal Conductivity of Dielectrics Phys. Rev. 60, 820-821 (1941). J. S. Blakemore Solid State Physics, 2nd ed., (Cambridge University Press, Cambridge, UK, 1985). J. Callaway Model for Lattice Thermal Conductivity at Low Temperature Phys. Rev. 113, 1046-1051 (1959). P. G. Klemens Thermal Conductivity of Solids at Low Temperature, in Encyclopedia of Physics, Vol. 14, edited by S. Fl€ ugge (Springer-Verlag, Berlin, 1956), pp. 198-281. R. Berman and J. C. F. Brock The E¡ect of Isotopes on Lattice Heat Conduction. I: Lithium Fluoride Proc. R. Soc. A289, 46-65 (1965). N. V. Novikov, A. P. Podoba, S. V. Shmegara, A. Witek, A. M. Ziatsev, A. B. Denisenko, W. R. Fahrner, and M. Werner In£uence of Isotopic Content on Diamond Thermal Conductivity Diamond Rel. Mat. 8, 1602-1606 (1999). R. Peierls Kinetic Theory of Thermal Conduction in Dielectric Crystals Ann. Phys., Leipzig 3, 1055 (1929). G. Leibfried and E. Schl€omann Thermal Conductivity of Dielectric Solids by a Variational Technique Nachr. Akad. Wiss. G€ottingen II a(4), 71 (1954). G. A. Slack and S. Galginaitis Thermal Conductivity and Phonon Scattering by Magnetic Impurities in CdTe Phys. Rev. 133, A253-A268 (1964). R. O. Pohl In£uence of F Centers on the Lattice Thermal Conductivity in LiF Phys. Rev. 118, 14991508 (1960). B. K. Agrawal and G. S. Verma Lattice Thermal Conductivity of Solid Helium Phys. Rev. 128, 603605 (1962).

20

Chap. 1.1

THEORY OF THERMAL CONDUCTIVITY

57. R. M. Kimber and S. J. Rogers The Transport of Heat in Isotopic Mixtures of Solid Neon: An Experimental Study Concerning the Possibility of Second-Sound Propagation J. Phys. C 6, 2279-2293 (1973). 58. P. G. Klemens Scattering of Low Frequency Phonons by Static Imperfections Proc. Phys. Soc. London A68, 1113-1128 (1955). 59. B. Abeles Lattice Thermal Conductivity of Disordered Semiconductors at High Temperatures Phys. Rev. 131, 1906-1911 (1963). 60. F. R. N. Nabarro The Interaction of Screw Dislocations and Sound Waves Proc. R. Soc. A209, 278290 (1951). 61. R. O. Pohl Thermal Conductivity and Phonon Resonance Scattering Phys. Rev. Lett. 8, 481-483 (1962). 62. J. M. Ziman The E¡ect of Free Electrons on Lattice Conduction Phil. Mag. 1, 191-198 (1956); corrected Phil. Mag. 2, 292 (1957). 63. A. Griffin and P. Carruthers Thermal Conductivity of Solids.IV: Resonance Fluorescence Scattering of Phonons by Electrons in Germanium Phys. Rev. 131, 1976-1992 (1963). 64. A. B. Pippard Ultrasonic Attenuation in Metals Phil. Mag. 46, 1104-1114 (1955). 65. P. Lindenfeld and W. B. Pennebraker Lattice Thermal Conductivity of Copper Alloys Phys. Rev. 127, 1881-1889 (1962). 66. L. G. Radosevich and W. S. Williams Thermal Conductivity of Transition Metal Carbides J. Am. Ceram. Soc. 53, 30-33 (1970).

Chapter 1.2

THERMAL CONDUCTIVITY OF METALS Ctirad Uher Department of Physics, University of Michigan, Ann Arbor, MI 48109, USA

1. INTRODUCTION Metals represent a vast number of materials that have been the backbone of industrial development during the past two centuries. The importance of this development upon future technological progress is undiminished and unquestionable. Whether in pure, elemental form or as new lightweight, high-strength alloys, metals are simply indispensable to modern industrial society. Metals are, of course, known for their lustrous and shiny appearance, for their malleability and ductility and, above all, for their ability to conduct electric current. Because of their myriad applications, it is highly desirable to be able to tailor the properties of metals to match and optimize their use for speci¢c tasks. Often among the important criteria is how well a given metal or alloy conducts heat. The physical parameter that characterizes and quanti¢es the material’s ability to conduct heat is called thermal conductivity, often designated by . Understanding the nature of heat conduction process in metals and being able to predict how well a particular alloy will conduct heat are issues of scienti¢c and technological interest. In this section we review the fundamental physical principles that underscore the phenomenon of heat conduction in metals, develop an understanding of why some metals are better than others in their ability to conduct heat, and illustrate the behavior of thermal conductivity on several speci¢c examples encompassing pure metals and alloys.

22

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

1.1. Carriers of Heat in Metals Metals are solids* and as such they possess crystalline structure where the ions (nuclei with their surrounding shells of core electrons) occupy translationally equivalent positions in the crystal lattice. We know see Chapter (1.1) that crystalline lattices support heat £ow when an external thermal gradient is imposed on the structure. Thus, like every other solid material, metals possess a component of heat conduction associated with the vibrations of the lattice called lattice (or phonon) thermal conductivity, p . The unique feature of metals as far as their structure is concerned is the presence of charge carriers, speci¢cally electrons. These point charge entities are responsible not just for the transport of charge (i.e., for the electric current) but also for the transport of heat. Their contribution to the thermal conductivity is referred to as the electronic thermal conductivity e . In fact, in pure metals such as gold, silver, copper, and aluminum, the heat current associated with the £ow of electrons by far exceeds a small contribution due to the £ow of phonons, so, for all practical purposes (and essentially for the entire regime of temperatures from sub-Kelvin to the melting point), the thermal conductivity can be taken as that due to the charge carriers. In other metals (e.g., transition metals and certainly in alloys) the electronic term is less dominant, and one has to take into account the phonon contribution in order to properly assess the heat conducting potential of such materials. In discussions of the heat transport in metals (and in semiconductors), one makes an implicit and essential assumption that the charge carriers and lattice vibrations (phonons) are independent entities. They are described by their respective unperturbed wave functions, and any kind of interaction between the charge carriers and lattice vibrations enters the theory subsequently in the form of transitions between the unperturbed states. This suggests that one can express the overall thermal conductivity of metals (and other solids) as consisting of two independent terms, the phonon contribution and the electronic contribution: ¼ e þ p :

ð1Þ

These twoelectrons and phononsare certainly the main heat carrying entities. However, there are other possible excitations in the structure of metals, such as spin waves, that may, under certain circumstances, contribute a small additional term to the thermal conductivity. For the most part, we shall not consider these small and often conjectured contributions. It is important to recognize that the theory of heat conduction, whether in nonmetallic or metallic systems, represents an exceptionally complex many-body quantum statistical problem. As such, it is unreasonable to assume that the theory will be able to describe all the nuances in the heat conduction behavior of any given material or that it will predict a value for the thermal conductivity that exactly matches that obtained from experiment. What one really hopes for is to capture the general trend in the behavior of the thermal conductivity, be it among the group of materials or in regard to their temperature dependence, and have some reasonably reliable guidelines and perhaps predictive power as to whether a particular

*

We consider here metals in their solid form only.

Measurements of thermal conductivity are among the most di⁄cult of the transport studies, and the accuracy of the data itself is usually no better than 2%.

Sec. 1

INTRODUCTION

23

class of solids is likely to be useful in applications where heat carrying ability is an important concern or consideration. The theory of heat conduction has been outlined in Chapter 1.1. There are numerous other monographs and review articles where this topic is treated in detail. I am particularly fond of the following texts: Berman’s Thermal Conduction in Solids, 1 Ashcroft and Mermin’s Solid State Physics,2 Ziman’s Electrons and Phonons,3 Smith and Jensen’s Transport Phenomena,4 and Mahan’s Many-Particle Physics.5 The level of coverage varies from an introductory treatment to a comprehensive quantum statistical description. On one hand, a too elementary description is unlikely to provide much more beyond an outline of the phenomenon ; on the other hand, a many-body quantum statistical exposure is likely to overwhelm most readers and, more often than not, its results are very di⁄cult to apply in practice or use as a guide. I will therefore settle here on a treatment that captures the essential physics of the problem, provides the formulas that describe the behavior of thermal conductivity in metallic systems, and has some predictive power regarding the choice of materials in various applications where heat conduction is an important issue. Because of the obvious practical relevance of noble metals such as copper, gold and silver and of various alloys containing copper, there has always been a strong interest in comparing the current and heat conducting characteristics of these materials. It is therefore no surprise that certain important empirical relations were discovered nearly 50 years before the concept of an electron was ¢rmly established and some 80 years before the notion of band structure emerged from the quantum theory of solids. Such is the case of the Wiedemann^Franz law,6 which states that, at a given temperature, the thermal conductivity of a reasonably pure metal is directly related to its electrical conductivity ; in other words, by making a simple measurement of electrical resistivity (conductivity equals inverse resistivity 1 Þ, we essentially know how good such a metal will be as a heat conductor, ¼ LT : ð2Þ In many respects, the Wiedemann^Franz law and the constant L that relates the thermal conductivity of pure metals to their electrical conductivity, called the Lorenz number,7 are the fundamental tenets in the theory of heat conduction in metals. Most of our discussion will focus on the conditions under which this law is valid and on deviations that might arise. Such knowledge is of great interest: on one hand it allows a fairly accurate estimate of the electronic thermal conductivity without actually performing the rather tedious thermal conductivity measurements; on the other hand, deviations from the Wiedemann^Franz law inform on the presence and strength of particular (inelastic) scattering processes that might in£uence the carrier dynamics. I wish to stress right here that the Wiedemann^Franz law strictly compares the electronic thermal conductivity with the electrical conductivity. In metals that have a substantial phonon contribution to the overall thermal conductivity (impure metals and alloys), forming the ratio with the measured values of the thermal and electrical conductivities will naturally lead to a larger magnitude of the constant L because the overall thermal conductivity will contain a signi¢cant contribution from phonons.

24

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

1.2. The Drude Model The ¢rst important attempt in the theoretical understanding of transport processes in metals is due to Paul Drude.8 This comes merely three years after J. J. Thomson9 discovered the electron, an elementary particle that clearly ¢ts the role of a carrier of charge in metals regardless of the fact that the convention for the positive current direction would much prefer a positively charged carrier. The classical free-electron model of metals developed by Drude builds on the existence of electrons as freely moving noninteracting particles that navigate through a positively charged background formed by much heavier and immobile particles. At his time, Drude had no idea of the shell structure of atomsnowadays we might be more speci¢c and say that the gas of electrons is formed from the conduction or valence electrons that are stripped from atoms upon the formation of a solid while the positively charged ions (nuclei surrounded by the core electrons) are the immobile particles located at the lattice sites. In any case, the classical electron gas is then described using the language of kinetic theory. In this picture, the straight-line thermal motion of electrons is interrupted by collisions with the lattice ions. Collisions are instantaneous events in which electrons abruptly change their velocity and completely ‘‘forget’’ what their direction of motion was just prior to the collision. Moreover, it is assumed that thermalization occurs only in the process of collisions; i.e., following a collision, although having a completely random direction of its velocity, the speed of the electron corresponds to the temperature of the region where the collision occurred. In de¢ning conductivities, it is advantageous ¢rst to introduce the respective current densities. Since electrons carry both charge and energy, their £ow implies both electric and heat currents. The term electric current density, designated Je , is understood to represent the mean electric charge crossing a unit area perpendicular to the direction of £ow per unit time. Let us assume a current £ows in a wire of cross-sectional area A as a result of voltage applied along the wire. If n is the number of electrons per unit volume and all move with the same average velocity v, then in time dt the charge crossing the area A is ^nevAdt. Hence, the current density is J e ¼ nev:

ð3Þ

In the absence of driving forces (electric ¢eld or thermal gradient), all directions of electron velocity are equally likely and the average velocity is zero; hence there is no £ow of charge or energy. If an electric ¢eld e is applied to an electron gas, electrons accelerate between the collisions and acquire a mean (drift) velocity directed opposite to the ¢eld: dv ee a ¼ : ð4Þ dt m Integrating Eq. (4), one obtains vðtÞ ¼

ee t þ vð0Þ m

ð5Þ

where v(0) is the velocity at t=0, i.e., right after the collision at which time the electric ¢eld has not yet exerted its in£uence. The apparently unlimited rise in the velocity v(t) with time is checked by a subsequent collision in which the electron is restored to a local thermal equilibrium. There will be a range of times between

Sec. 1

INTRODUCTION

25

collisions, so to ¢nd out the mean value of the velocity over all possible times t between collisions, we need to know how these times are distributed. The probability that an electron which has not collided with an ion during the time t will now su¡er a collision in the time interval t + t is P ðtÞdt ¼ The mean velocity then follows from v ¼

ee ee t¼ m m

et= dt:

Z t

ð6Þ

e-t= e dt ¼ e; m

ð7Þ

i.e., the mean time t between collisions is equal to , the parameter frequently called the collision time or relaxation time. After Eq. (7) is substituted into Eq. (3), the electric current density becomes Je ¼

ne2 e ¼ e; m

ð8Þ

from which one obtains the familiar expression for the electrical conductivity: ¼

ne2 : m

ð9Þ

Thus, the Drude Theory predicts the correct functional form for Ohm’s law. By de¢ning the mean free path between the collisions le as ð10Þ le ¼ v; We can write Eq. (9) as ¼

ne2 le : m v

ð11Þ

In Drude’s time, the mean speed of electrons was calculated by using the equipartition theorem, namely 1 3 mðvÞ2 ¼ kB T : ð12Þ 2 2 Thus, with the obtained mean velocity and using the experimental values of the electrical conductivity, the mean free path of metals at room temperature invariably , seemingly providing an excellent support for Drude’s came out in the range 1^5A model that assumed frequent collisions of electrons with ions on the lattice sites. Similar to the electric current density, one can de¢ne the thermal current density JQ as a vector parallel to the direction of heat £ow with a magnitude equal to the mean thermal energy per unit time that crosses a unit area perpendicular to the £ow. Because the speed of an electron relates to the temperature of the place where the electron su¡ered the most recent collision, the hotter the place of collision the more energetic the electron. Thus, electrons arriving at a given point from the hotter region of the sample will have higher energy than those arriving at the same point from the lower-temperature region. Hence, under the in£uence of the thermal gradient there will develop a net £ux of energy from the higher-temperature end to the lower-temperature side. If we take n/2 as both the number of electrons per unit volume arriving from the higher-temperature side and the same density of

26

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

electrons arriving from the lower-temperature region, and assuming that the thermal gradient is small (i.e., the temperature change over a distance equal to the collision length is negligible), it is easy to show that the kinetic theory yields for the heat current density the expression 1 J Q ¼ ‘e vcv ð=T Þ ¼ e =T : ð13Þ 3 Here le is the mean free path of electrons, cv is their electronic speci¢c heat per unit volume, and e is the thermal conductivity of electrons. Equation (13) is a statement of the Fourier law with the electronic thermal conductivity given as 1 e ¼ ‘e vcv : ð14Þ 3 Relying again on the classical description of the electron gas, Drude writes the speci¢c heat of electrons per unit volume cv in terms of the molar speci¢c heat cm : n 3 n 3 cv ¼ cm ¼ N A kB ¼ kB n: ð15Þ NA 2 NA 2 Substituting into Eq. (14) yields the classical expression for the thermal conductivity of electrons 1 3 nkB ‘e v e ¼ ‘e v kB n ¼ : ð16Þ 3 2 2 By forming the ratio e /, one arrives at the Wiedemann^Franz law: e nkB ‘e v=2 kB mðvÞ2 3 kB 2 ¼ 2 ¼ ¼ T: v ne ‘e =m 2e2 2 e

ð17Þ

In the last step in Eq. (17) the mean square velocity is taken in its Maxwell^ Boltzmann form 3kB T =m. Equation (17) is a crowning achievement of the Drude theoryit accounts for an empirically-well-established relation between thermal and electrical conductivities of metals, and the numerical factor 32 ðkB =eÞ2 = 1.1108 V2 =K2 is only a factor of 2 or so smaller than the experimental data*. Overall, the success of the Drude theory appears impressive, especially when viewed from the perspective of the early years of the 1900s, and for the next three decades it formed the basis of understanding of the transport properties of metals. In retrospect, the success of this theory is quite fortuitous and stems from a lucky cancellation of a couple of large and grossly erroneous parameters that have their origin in the use of classical statistics. The most blatant error comes from the classically calculated value of the electronic speci¢c heat, which grossly overestimates the actual electronic contribution to the heat capacity of metals. With its value of 3R/2 per mole, the classical electronic term is comparable to that due to the lattice and would result in far too large a speci¢c heat of metals. Experimentally, no such classical electronic contribution was ever seen. This outstanding puzzle in the classical theory of metals lasted until it was recognized that electrons * In his original paper, Drude makes a mistake in his evaluation of the electrical conductivity, which comes out only one-half of what Eq. (11) implies. With such an erroneous result his value for the Lorenz constant is 2.2108 V2 /K2 in excellent agreement with experimental values.

Sec. 2

INTRODUCTION

27

are fermions and their properties must be accounted for with Fermi^Dirac statistics. In the expression for the Wiedemann^Franz law, Eq. (17), this large error is compensated by a comparably large error arising from the mean square electronic speed which, in the classical Maxwell^Boltzmann form, is a factor of 100 smaller than the actual (Fermi) velocity of electrons. The fortuitous cancellation of these two large errors leaves the Lorenz constant approximately correct except for its numerical factor of 3/2. With Fermi^Dirac statistics this numerical factor becomes equal to 2 /3, in which case it is often stated that the Lorenz constant assumes its Sommerfeld value: L0 ¼

2 kB 2 ð Þ ¼ 2:44 108 V2 K2 : 3 e

ð18Þ

Such fortuitous cancellation does not extend to the electrical conductivity in Eq. (11) and classical statistics is responsible for underestimating the mean free path by a factor of 100. In reality, le should be on the order of several hundred angstroms rather than a few angstroms, as obtained by Drude. Actually there is another reason why Drude’s viewpoint of very frequent scattering of electrons on ions is not a good physical picture. With the advent of quantum mechanics it was soon recognized that, because the electrons have a wave nature (apart from their corpuscular character), a perfectly periodic lattice presents no resistance to the current of electrons and the electrical conductivity in that case should be in¢nite. It is only because of deviations from perfect periodicity that the electrical conductivity attains its ¢nite value. Imperfections can be of either dynamic nature and intrinsic to the structure, such as displacements of ions about the lattice sites due to thermal vibrations, or they can have a static character, such as impurities, vacancies, interstitials, and other structural defects. Another less than satisfactory outcome of the Drude theory that is a direct consequence of the classical treatment concerns the predicted temperature dependence of electrical resistivity. With the Maxwell^Boltzmann mean electron velocity, v ¼ ð3kB T =mÞ1=2 , the temperature dependence of resistivity is expected to be proportional to 1 m v ¼ ¼ 2 T 1=2 : ð19Þ ne ‘e Experimentally, the resistivity of metals at temperatures above the liquid nitrogen temperature is typically a linear function of temperature. Again, the discrepancy with the classical Drude model is eliminated when quantum mechanics is used, namely when the mean velocity is taken as the Fermi velocity. The fact that we talk about the Drude model some 100 years after its inception indicates that, in spite of its shortcomings, the model provided convenient and compact expressions for electrical and thermal conductivities of metals and, with properly calculated parameters, o¡ered a useful measure of comparison between important transport properties. Table 1 presents thermal and electrical conductivities of metals together with their Lorenz ratio, all referring to a temperature of 273 K.

28

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

TABLE 1 Thermal Conductivity of Pure Metals at 273 K.a

Metal

(W/m-K)

Ag Al Au Ba Be Ca Cd Ce Co Cr Cs Cu Dy Er Fe Ga (jj c) (jj a) (jj b) Gd Hf Hg (jjÞ (?Þ Ho In Ir K La Li Lu Mg Mn (Þ Mo Na Nb Nd Ni Os Pb Pd Pr Pt Pu Rb Re Rh Ru Sc Sm Sn Sr Ta Tb Tc

436 237 318 23.3 230 186 100 11.2 (291 K) 99 (300 K) 95.7 (280 K) 37 (295 K) 402 (300 K) 10.4 (291 K) 13.8 (291 K) 80.2 (280 K) 16.0 41.0 88.6 9.1 (291 K) 22.4 (293 K) 34.1 (197 K) 25.9 (197 K) 11.8 (300 K) 81.0 (280 K) 149 (277 K) 98.5 14.0 (291 K) 65 16.2 (291 K) 153 (301 K) 7.8 (291 K) 143 142 51.8 (280 K) 16.5 (291 K) 93 (280 K) 87 (323 K) 35.5 71.7 12.8 71.9 (280 K) 5.2 (298 K) 55.8 49 153 (280 K) 110 (280 K) 21.8 13.4 (291 K) 64 51.9 57.7 (280 K) 10.4 (291 K) 51 (300 K)

(108 m)

L (108 V2 /K2 )

1.47 2.34 2.43 2.10 2.03 2.39 29.8 2.55 2.8 2.36 3.08 2.13 6.80 2.49 80.0 3.5 5.99 1.98 (300 K) 11.8 4.11 18.0 2.5 (295 K) 1.73 (300 K) 2.31 (300 K) 93 3.75 (291 K) 79 3.75 (291 K) 8.64 2.57 (280 K) 50.3 2.95 16.1 2.41 7.5 2.43 128 4.2 (291 K) 31.0 (293 K) 2.45 (293 K) 14.6 (197 K) 2.53 (197 K) 19.3 (197 K) 2.55 (197 K) 78.0 (300 K) 3.2 (300 K) 8.25 (280 K) 2.39 (280 K) 4.70 2.57 (277 K) 6.20 2.24 59 2.9 8.5 2.05 50 3.3 (291 K) 4.5 (301 K) 2.29 (301 K) 137 4.0 (291 K) 4.88 2.56 4.29 2.23 13.3 2.53 (280 K) 58 3.7 (291 K) 6.24 2.19 (280 K) 8.3 2.7 (323 K) 19.2 2.50 9.74 2.57 65 3.1 (280 K) 9.82 2.59 (280 K) 130 2.48 (298 K) 11.3 2.30 16.9 3.05 4.35 2.46 (280 K) 6.7 2.72 (280 K) 44 4.3 90 4.3 (291 K) 10.6 2.48 11.0 2.18 12.1 2.56 (280 K) 110 4.25 (291 K) 16.7 3.4 (300 K)

Ref.

11 12 13 14 15 16 15 17 18 19 20 21 22 22 23 19 19 24 22 25 26 26 27 28 29 30 22 31 22 32 22 33 34 35 22 36 29 37 38 39 23 40 41 42 43 43 44 22 15 14 45 22 46

Sec. 2

SPECIFIC HEAT OF METALS

Metal

(W/m-K)

(108 m)

Th Ti Tl U V W Y Zn Zr As (pc) (? c-axis) (jj c-axis) Bi (pc) (? c-axis) (jj c-axis) Sb

49.3 22.3 50.6 28 (278 K) 35 (260 K) 183 (280 K) 15.9 (291 K) 114.5 (283 K) 20.5 (323 K) 27 (298 K) 51.0 (300 K) 29.0 (300 K) 7.8 (298 K) 9.8 (300 K) 6.0 (300 K) 18.2

13.9 40 15 24 18.9 4.85 52 5.5 39 31.7 (298 K) 28.4 (300 K) 38.6 (300 K) 148 (298 K) 112 (300 K) 135 (300 K) 43

29 L (108 V2 /K2 )

2.56 3.25 2.8 2.8 (278 K) 2.4 (260 K) 3.27 (280 K) 2.9 (291 K) 2.31 (283 K) 3.4 (323 K) 2.87 (298 K) 4.83 (300 K) 3.73 (300 K) 3.87 (298 K) 3.65 (300 K) 2.69 (300 K) 2.87

Ref.

47 48 49 50 51 23 22 52 53 54 55 55 56 57 57 58

a.

The data also include values of electrical resistivity and the Lorenz number. Most of the data are taken from the entries in the extensive tables in Landolt-Bo«rnstein, New Series10 .

2. SPECIFIC HEAT OF METALS One of the major problems and an outstanding puzzle in the Drude picture of metals was a much too large contribution electrons were supposed to provide toward the speci¢c heat of metals. While the classical treatment invariably suggested an additional 3R/2 contribution to the molar speci¢c heat of metals (on top of the 3R term due to the lattice vibrations), the experimental evidence was unequivocal: the speci¢c heat of simple solids at and above room temperature did not distinguish between insulators and metals, and the measurements yielded values compatible with the Dulong^Petit law; i.e., the molar speci¢c heat of 3R = 6 cal mole1 K1 = 25 J mole1 K1 . This puzzle was solved when electrons were treated as quantum mechanical objects and described in terms of Fermi^Dirac statistics. We brie£y outline here the key steps. Having half-integral spin, electrons are classi¢ed as Fermi particles (fermions) and are subject to the Pauli exclusion principle. As intrinsically indistinguishable particles, symmetry requirements imposed on the wave function of electrons are such that no two electrons are allowed to share the same quantum state, i.e., to possess identical sets of quantum numbers. This fundamental restriction has farreaching consequences as to how to treat the electrons, how to ‘‘build up’’ a metal, and, for that matter, how to assemble elements in the periodic table. The statistics that guarantee that the Pauli principle is obeyed were developed by Fermi and Dirac, and the distribution of fermions governed by these statistics is referred to as the Fermi^Dirac distribution fðE; T Þ: 1 : ð20Þ fðE; T Þ ¼ ðEÞ=k T B þ1 e Here is the chemical potential, often referred to as the Fermi level or Fermi energy and written as EF instead of . Equation (20) expresses the probability of ¢nding an electron in a particular energy state E and has a very interesting prop-

30

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

erty. At T =0 K, the function f(E; T ) is a step function that sharply divides the occupied states from the unoccupied states, with the Fermi energy playing the demarcation line between the two. At E < EF , all available single-electron states are fully occupied while for E > EF all states are empty. The Fermi energy is thus the highest occupied energy state. As the temperature increases, a certain degree of ‘‘smearing’’ takes place at the interface between the occupied and unoccupied states, with states close to but below EF now having a ¢nite probability of being unoccupied, while states close to but slightly above EF have a ¢nite chance to be occupied. The range of energies over which the distribution is smeared out is fairly narrow and amounts to only about 4kB T around the Fermi level. Since the Fermi energy of typical metals is several electron^volts (eV) while the value of 4kB T at 300 K is only about 100 meV, the smearing of the distribution is indeed small on the fundamental energy scale of metals. Nevertheless, this lack of sharpness in the distribution of electrons is all-important for their physical properties. Because the deep lying electron states are fully occupied with no empty states in the vicinity, electrons occupying such states cannot gain energy nor can they respond to external stimuli such as an electric ¢eld or thermal gradient. Only electrons within the smeared-out region of the distribution have empty states accessible to them and can thus absorb the energy. Of the entire number of free electrons constituting a metal, it is thus only a fraction 4kB T =EF (0.01) of them that are involved in the speci¢c heat. This is the reason why one does not detect electronic contribution to the speci¢c heat of metals at and above ambient temperatures; the contribution of electrons is simply too small on the scale of the Dulong^Petit law. To calculate the speci¢c heat due to electrons exactly within the single-electron approximation, apart from their distribution function, one also needs to know the number of energy states per unit volume in a unit energy interval, i.e., the density of states, D(E). This quantity is model dependent. Regardless of the model chosen for D(E), its product with the distribution function integrated over all energies of the system must yield the density of electrons per unit volume: Z1 DðEÞfðE; T ÞdE: ð21Þ n¼ 0

When electrons are heated from absolute zero temperature to some ¢nite temperature T, they absorb energy and increase their internal energy by ZEF 0

Z1 EDðE Þf ðE; T ÞdE

U ðT Þ ¼ 0

EDðE ÞdE:

ð22Þ

0

The second integral in Eq. (22) represents the internal energy of electrons U(0) at T=0 K. Electrons have this non-zero internal energy at absolute zero purely because they obey the Pauli exclusion principle, and only two electrons out of n electrons (one with spin up and one with spin down) can occupy the lowest energy state. All other electrons have to be accommodated on the progressively higher energy levels, hence a signi¢cant internal energy even at T=0 K. By di¡erentiating with respect to temperature and employing a trick of subtracting a term the value of which is zero but the presence of which allows one to express the result in a

Sec. 2

SPECIFIC HEAT OF METALS

31

convenient form,* we obtain Z1 cv ¼

ðE EF ÞDðEÞ 0

@fðE; T Þ dE: @T

ð23Þ

Assuming that the density of states does not vary much over the narrow temperature range where the distribution function is smeared out around the Fermi energy, (i.e., taking the density of states at its value of the Fermi energy EF and carrying out the partial derivative of the distribution function), one obtains Zþ1 x2 ex 2 2 2 cv ¼ kB T DðEF Þ dx ¼ k T DðEF Þ: ð24Þ 3 B ðex þ 1Þ2 1

This is a general result for the speci¢c heat per unit volume of electrons, independent of a particular form of the density of states. For a free-electron gas, it is easy to show that the density of states becomes DðEÞ ¼

ð2mÞ3=2 1=2 E : 22 h3

ð25Þ

In that case, the density of electrons per unit volume can be conveniently expressed as 2 n ¼ DðEF ÞEF ; ð26Þ 3 and with the de¢nition of the Fermi temperature TF = EF /kB , the heat capacity per unit volume becomes cv ¼

2 T nkB : 2 TF

ð27Þ

Comparing with Eq. (15), one sees that the e¡ect of Fermi^Dirac statistics is to lower the speci¢c heat of electrons by a factor of (2 /3)(T =TF Þ. Because the Fermi temperature of metals is very high, 104 105 K, this factor is less than 0.01 even at room temperature. To get from the speci¢c heat per unit volume into a more practically useful quantityspeci¢c heat per mole of the substanceEq. (27) must be multiplied by the volume per mole, ZNA =n, where ZNA is the number of electrons in a mole of metal of valence Z and NA stands for Avogadro’s number : C¼

2 T 2 T ZkB NA ¼ ZR ¼ T : 2 TF 2 TF

ð28Þ

In Eq. (28), R is the universal gas constant and , the coe⁄cient of the linear speci¢c heat of metals, is often called the Sommerfeld constant. Although the magnitude of the electronic speci¢c heat is small, and certainly at ambient temperature it is negligible compared to the lattice contribution, it gains importance at low *

Because of the high degeneracy of electrons, the electron density n in Eq. (21) is a constant and by multiplying it by the value of the Fermi energy, the product EF n remains temperature independent. R Di¡erentiating it with respect to temperature gives 0= EF D(E)(F/T)dE. This term is then subtracted from the derivative of Eq. (22) with respect to temperature to obtain Eq. (23).

32

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

temperatures. Because the lattice speci¢c heat decreases with a much faster T 3 power law, there will be a crossover temperature (typically a few kelvins) below which a slower, linear dependence of the electronic contribution will start to be manifested and eventually will become the dominant contribution. It is interesting to compare experimental values of the coe⁄cient of selected metals with the corresponding free-electron values given by Eq. (28). In essence, such a comparison (see Table 2) informs how appropriate it is to describe the electrons of each respective metal as being free electrons. We note that for the noble metals and the alkaline metals the free-electron description is a reasonable starting point, while for most of the transition metals the free-electron picture is grossly inadequate. The large deviations between the experimental and free-electron -values observed in the case of transition metals are believed to arise from a very high density of states of the d-electrons near the Fermi energy. Transition metals are characterized by their incomplete d-shells. When transition metals form by bringing together atoms, the two outer s-electrons split o¡ and go into a wide conduction band. The more tightly bound d-electrons also form a band, but this is a rather narrow band because the overlap between the neighboring d-orbitals is small. Nevertheless, this band must be able to accommodate 10 electrons per atom, hence its large density of states. On the other hand, semimetals such as Sb and Bi possess very low values of the parameter because their carrier density is several orders of magnitude less than that of a typical metal. 3. THE BOLTZMANN EQUATION When one talks about transport phenomena, one means processes such as the £ow TABLE 2 Comparison of Experimental and Calculated (free-electron) Values of the Coe⁄cient of the Electronic Speci¢c Heat for Selected Metals.a:

Metal

Na K Ag Au Cu Ba Ca Sr Co Fe Ni Al Ga Sn Pb As Sb Bi

Valence

Free-electron (10 3 J mole 1 K 2 )

Experimental (10 3 J mole 1 K 2 )

1 1 1 1 1 2 2 2 2 2 2 3 3 4 4 5 5 5

1.09 1.67 0.64 0.64 0.50 1.95 1.51 1.80 0.61 0.64 0.61 0.91 1.02 1.39 1.50 1.30 1.63 1.79

1.7 1.7 0.66 0.67 0.69 2.72 2.72 3.64 4.98 5.02 7.02 1.30 0.63 1.84 2.93 ^ 0.628 0.08

a. Experimental values are taken from Ref. 2.

Sec. 3

THE BOLTZMANN EQUATION

33

of charge or £ow of heat in solids. One is usually concerned about the steady-state £ow, i.e., the £ow established as a result of the in£uence of external driving forces (electric ¢eld or thermal gradient in our case) and the internal scattering processes tending to restore the system to equilibrium. A steady state therefore must be distinguished from the equilibrium state, and transport theory is thus a special branch of nonequilibrium statistical mechanics. The deviations from the truly equilibrium state, however, are usually small. The questions are: how are the driving forces and the scattering processes interrelated ? and how does the population of the species under investigation evolve as a function of time? The answers are provided by the Boltzmann equation. Although there are other approaches describing how to treat the problem and arrive at formulas for the transport parameters, the Boltzmann equation has proven itself time and again as the most versatile approach and the one that is reasonably easy to track. Moreover, it yields a form of the expressions for the transport parameters that are intuitive and that can readily be compared with the experimental results. In this section we show how one uses the Boltzmann equation to arrive at useful formulas for the transport parameters of metals. Metals are crystalline solids. The periodic potential of ions located at the crystal lattice sites is an essential feature of the system and must be incorporated in a realistic description of metals. Lattice periodicity has the following consequences : the momentum of a free electron is replaced by a quantity hk, where k is the Bloch wave vector of an electron. The wave vector contains information about the translational symmetry of the lattice. The electron velocity, which in the free-electron model is simply v = p/m, is replaced by the group velocity (1/h)@E(k)/@k, where E(k) is the Bloch energy of an electron. Wave functions, which in the free-electron picture were simply plane waves exp(ikr ), must now re£ect the periodicity of the lattice. This is accomplished by introducing Bloch waves k (r) = uk (r)exp(ikr ), i.e., plane waves modulated by a function uk (r) that has the periodicity of the lattice. The fundamental issue concerns the distribution function of electrons in a metal, i.e., how the occupation number of electrons changes as a result of the in£uence of an electric ¢eld and thermal gradient, and the e¡ect of various scattering processes that the electrons undergo. The equilibrium distribution of electrons is governed by the Fermi^Dirac function [Eq. (20)], which is independent of the spatial coordinate r because of the assumed homogeneity (in equilibrium, the temperature is the same everywhere). Away from equilibrium, the distribution may depend on the spatial coordinate r, since we assume that local equilibrium extends only over the region larger than the atomic dimensions, and of course on the time t. Moreover, because the energy of electrons is a function of the wave vector, we also assume that the distribution function depends on k. We therefore consider explicitly f(r,k,t). Temporal changes in f(r,k,t) arise because of three in£uences: 1. Electrons may move in or out of the region in the vicinity of point r as a result of di¡usion. 2. Electrons are acted upon by driving forces such as an electric ¢eld or thermal gradient. 3. Electrons are de£ected into and out of the region near point r because they scatter on lattice vibrations or on crystal imperfections. This is the scattering in£uence on the distribution function, and the respective partial derivative is called the collision term.

34

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

The ¢rst two in£uences on f(r,k,t) have their origin in the Liouville theorem concerning the invariance of the volume occupied in phase space. Thus, the number of electrons in the neighborhood of point r at time t must equal the number of electrons in the neighborhood of point r ^ v(k)dt at the earlier time t - dt. Since the electrons are also subjected to an external electric ¢eld E, they accelerate and in time dt change their momentum hk by (dk/dt)dt = e e dt=h. (We assume that there is no magnetic ¢eld present.) Therefore, in analogy with the Liouville theorem for the spatial coordinate r, we consider the same volume invariance but this time for k-space; i.e., the electrons that are at point k at time t must have been at a location k ^ (^e) e dt=h at time t ^ dt. In the absence of any kind of collisions, we therefore can write dt f ðr; k; tÞ ¼ f r vðkÞdt; k þ ee ; t dt : ð29Þ h However, collisions cannot be neglected since they change the population of electrons. Some electrons will be de£ected away from the stream of electrons during the time interval dt as the electrons proceed from (r ^ v(t)dt, k + ee dt=h) to (r, k). However, it is also possible that some electrons that arrive at (r, k) at time t do not belong to the stream of electrons we considered at (r ^v(t)dt, k + ee dt=h) at time t - dt because they were de£ected into the stream by collisions in the neighboring regions during the time dt. It is customary to capture both the ‘‘out-de£ected’’ and ‘‘in-de£ected’’ electrons in a term (@f/@t)coll . Thus, in time dt there will be a change of population due to scattering of magnitude (@f/@t)coll dt. Putting it all together, we write 8 9 dt df : > ; dt: f ðr; k; tÞ ¼ f r vðkÞdt; k þ ee ; t dt þ > ð30Þ h dt coll Expanding the equation to terms linear in dt, one obtains the Boltzmann equation: 8 9 @f ee @f ; : : > þ v rr f :rk f ¼ > ð31Þ @t h @t coll Equation (31) describes a steady state, not the equilibrium state. The terms on the left-hand side are frequently called the streaming terms. In principle, the collision term on the right-hand side contains all the information about the nature of the scattering. Using the quantum mechanical probability for transitions between the Bloch states k and k 0, speci¢cally Wkk0 / j j2 , where H 0 is the perturbation Hamiltonian, one can write the collision term as Z 9 8 @f ðkÞ> V > ; ¼ : dk0 f½1 f ðkÞWkk0 f ðk0 Þ ½1 f ðk0 ÞWk0 k f ðkÞg ð32Þ @t coll ð2Þ3 The two terms in braces represent transitions from the occupied state k0 to an empty state [1 ^ f(k)] and a corresponding transition from the occupied state k to an empty state [1 ^ f(k0 Þ]. These terms are present to comply with the Pauli exclusion principle. Substituting Eq. (32) into Eq. (31), one gets a complicated integrodi¡erential equation for the distribution function f(r,k,t). One of the most successful approaches for solving the Boltzmann equation relies on the use of a relaxation time approximation. The essence of this approach is the assumption that scattering processes can be described by a relaxation time (k) that speci¢es how the system returns to equilibrium, i.e., how the distribution function

Sec. 3

THE BOLTZMANN EQUATION

35

f(r,k,t) approaches its equilibrium value f o (k). One therefore writes the collision term as 8 9 @f f ðkÞ f o ðkÞ g ðk Þ > ; ¼ : > ¼ ; ð33Þ @t coll ðkÞ ðkÞ where g(k) is the deviation of the distribution function f(k) from its equilibrium value f o (k), and (k) is the relaxation time. Further considerable simpli¢cation of the transport problem is achieved by linearization of the Boltzmann equation. This is done simply by replacing the steady-state electron distribution in the gradients rr f(r,k,t) and rk f(r,k,t) by the equilibrium distribution function, i.e., by taking rr f(r,k,t) = rr f o (r,k) and rk f(r,k,t) = rk f o (r,k). This seems eminently reasonable provided that the external ¢elds are not too strong so that the steady-state distribution is not too far from equilibrium. We can easily evaluate these two respective gradients (including speci¢cally the dependence of the Fermi energy on temperature) and rewrite Eq. (31) as 8 9 9 8 @f o > E EF 1 @f > ;vðkÞ : ; : > rr T e e rr EF ¼> ð34Þ @E T e @t coll This is the linearized Boltzmann equation. After some algebra, we can write, for the perturbed distribution function f(r,k,t), 8 8 9 9 @f o > 1 E EF o > > > : ; : ; f ðk Þ ¼ f ðk Þ þ vðkÞ ðkÞ e e rr EF þ ðrr T Þ : ð35Þ @E e T This is a general form of the distribution function describing electron population perturbed by a weak electric ¢eld and a small temperature gradient. Before we proceed further it is important to comment on the quantity we call the relaxation time (k). It is a major consideration whether (k) is a true relaxation time in the sense of representing something like the time between collisions and, therefore, whether it faithfully represents the way the equilibrium state is approached. We can, of course, always formally introduce the parameter (k) for any process, but if this quantity turns out to depend on a particular form of the ¢eld that created the out-ofequilibrium state, then we would need di¡erent functional forms of (k) for di¡erent external ¢elds and the meaning we associate with the relaxation time would be lost. Thus, whether the true relaxation time exists (i.e., whether the relaxation time approximation is valid) is a critical issue, and we shall see that it has a decisive in£uence on the discourse concerning the thermal conductivity at low temperatures. 3.1. Transport Coef¢cients Knowing how a weak electric ¢eld and a thermal gradient perturb the population of electrons, we may now proceed to inquire what currents arise when the system is allowed to reach steady state. To do that, it is customary to de¢ne current densities. If we consider a £ow of particles, we know that a volume element dk around point k in reciprocal space will contribute a £ux of particles of magnitude (1/83 Þv(k)dk, where v(k) is the particle velocity. Since we consider electrons, there are two spin states for every k-state and the electrons are distributed according to the Fermi^ Dirac function. Summing over all available states and assigning a charge e to each electron, we obtain the current density:

36

Chap. 1.2

Je ¼

2e 83

THERMAL CONDUCTIVITY OF METALS

Z vðkÞf ðkÞdk:

Similarly for the heat current density, we write Z 2 JQ ¼ 3 vðkÞ½E f ðkÞdk: 8

ð36Þ

ð37Þ

Equation (37) contains a term E , where is the chemical potential (free energy, which in metals can be taken as the Fermi energy) rather than just energy E. This is necessary because thermodynamics tells us that heat is internal energy minus free energy. Since equilibrium distributions do not generate currents (there is no spontaneous current £ow), substituting the perturbed distribution function in Eq. (35) into Eq. (36) causes the integral containing the equilibrium distribution to vanish. The remaining term is Z 9 8 2e @f o > E > ; ee r þ Je ¼ 3 vðkÞvðkÞ : ðrT Þ dk 8 @E T e2 ¼ 3 h 4 e þ 3 4 h

Z

Z

9 8 @f o > 1 dS > ; e r vðkÞvðkÞ: dE @E e jvj 8 9 @f o > E dS > : ; vðkÞvðkÞ ðrT Þ dE: @E T jvj

ð38Þ

Similarly, substituting Eq. (35) into Eq. (37) results in Z 9 8 2 @f o > E ; ee r þ : JQ ¼ 3 vðkÞvðkÞ > ðrT Þ ðE Þdk 8 @E T e ¼ 3 4 þ 3 4

Z

9 8 1 @f o > dS ; dE : vðkÞvðkÞ e r ðE Þ> e @E jvj

Z

9 8 E @f o > dS > ; dE; : vðkÞvðkÞ ðrT Þ T @E jvj

ð39Þ

where, with the aid of dk = dSdk? = dSdE=jrk Ej, we converted an integral over a volume in k-space into an integral over surfaces of constant energy. De¢ning now the integral ZZ 8 9 1 @f o > dS : ; dE; Kn ¼ 3 vðkÞvðkÞðE Þn > ð40Þ 4 h @E jvj we can express Eqs. (38) and (39) in terms of Kn : eK1 J e ¼ e2 K o e þ ðrT Þ; T JQ ¼ eK1 e þ

K2 ðrT Þ: T

ð41Þ ð42Þ

Sec. 3

THE BOLTZMANN EQUATION

37

Equations (41) and (42) reveal an important pointelectric current Je can be generated not just by an external electric ¢eld but also by a thermal gradient. Likewise, heat current JQ arises as a result of an electric ¢eld and a thermal gradient. In essence, there are interactions between the electric and heat currents. Integrals Kn ; de¢ned in Eq. (40), can be evaluated, using a general theorem for integrals of the Fermi function over energy that are of the form Zþ1 Zþ1 9 8 @f o > ;dE; : ðE Þf ðE ÞdE ¼ ð E Þ> ð43Þ @E 1

1

where (E) = d(E)/dE. Because -@f o /@E has an appreciable value only within a few kB T of , a smoothly varying function of energy (E) can be expanded about E ¼ , where hopefully only the ¢rst few terms su⁄ce for accuracy : 1 X ð E Þ n dn ð E Þ ðE Þ ¼ ð Þ þ ð44Þ n! dE n E¼ n¼1 The integral in Eq. (43) then becomes Z 8 9 @f o > 2 ð kB T Þ 2 @ 2 ð E Þ : ;dE ¼ ð Þ þ ðE Þ> þ:::; @E 6 @E 2 E¼

ð45Þ

and only terms even in n contribute because @f o /@E is an even function of E . Equations (41) and (42) serve to de¢ne transport coe⁄cients in zero magnetic ¢eld. The usual isothermal electrical conductivity follows from a condition that the thermal gradient is zero: Je ¼ e2 Ko e:

ð46Þ

With the explicit form of Ko , this can be written as Z e 2 ðE F Þ dSF Je ¼ 3 vðkÞvðkÞ e ¼ e; 4 h jvðkÞj

ð47Þ

E¼EF

where is the electrical conductivity. In a general crystal structure the current density need not be parallel to the electric ¢eld, and the electrical conductivity is a tensor, Z e2 ðEF Þ vi ðkÞvj ðkÞdSE ij ¼ : ð48Þ 3 h 4 jvðkÞj E¼EF

For cubic metals and for isotropic (i.e., polycrystalline metals), the tensor reduces to a scalar. Placing now the electric ¢eld e along, say, the x-direction, we obtain, making use of v2x = (1/3)v2 : Z Z e2 ðEF Þ e2 ¼ vdSE ¼ ‘e dSE : ð49Þ h 123 123 h E¼EF

E¼EF

In this equation, we introduced the mean free path of electrons as je = v: (EF Þ. Equation (49) is the basic formula for the electrical conductivity. It states clearly that only electrons near the Fermi level can contribute to the transport process

38

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

since the integral is over the Fermi surface E(k) = EF . This, of course, is in full agreement with the Pauli exclusion principle. One might think that the thermal conductivity is obtained simply by taking it as a coe⁄cient of the thermal gradient in Eq. (42), i.e., under the conditions that an external electric ¢eld is zero. However, this is not how thermal conductivity is measured. Although it is di⁄cult to control electric ¢elds, it is a straightforward matter to ensure that no electric current passes through the sample while the thermal conductivity is measured. We simply leave the sample in open-circuit con¢guration. Therefore, to obtain the desired coe⁄cient of thermal conductivity, we set the current Je = 0 in Eq. (41) and express an electric ¢eld in terms of a thermal gradient: e¼

Ko1 K1 rT : eT

ð50Þ

Substituting Eq. (50) into Eq. (42) yields 1 JQ ¼ K2 K1 Ko1 K1 ðrT Þ ¼ ðrT Þ: T

ð51Þ

The coe⁄cient is the electronic thermal conductivity. The term K1 Ko1 K1 in Eq. (51) is very small for metals and, for present purposes, can be neglected. The thermal conductivity is therefore K2 1 ¼ K2 K1 Ko1 K1 ﬃ : ð52Þ T T If we de¢ne a function (E) = (E EF Þ2 Ko (E), it can be shown, using Eq. (45) and noting that the term [(E)]E¼EF = 0, that K2 is related to Ko via 2

K2 ¼

2

2 ðkB T Þ 2 ðkB T Þ 2Ko ðEF Þ ¼ K o ðE F Þ 6 3

Substituting Eq. (53) into Eq. (52), we obtain the thermal conductivity as 8 9 K2 2 k2B T 2 >kB >2 ¼ ¼ Ko ðEF Þ ¼ : ; T T 3 3 e

ð53Þ

ð54Þ

We recognize the ratio / as the Lorenz number of the Wiedemann^Franz law. Equation (54) is to be compared to the Drude result [Eq. (18)], where the only di¡erence is in the factor 2 /3 = 3.29 in place of 3/2, arising because Eq. (54) is derived with the proper statistical description of the electrons. Eq. (54) is quite a general result except for the fact that scattering processes must be elastic. Now that the coe⁄cients governing the £ow of charge, , and the £ow of heat, , have been established, two other coe⁄cients remain to be determined based on Eqs. (41) and (42). These represent the interference terms between the electric and thermal ¢elds. Let us assume that we set up a temperature gradient across a sample that is in open-circuit con¢guration ; i.e., there is no electric current Je . This gradient gives rise to an electric ¢eld ": "¼

Ko1 K1 rT ¼ SrT : eT

ð55Þ

Sec. 3

THE BOLTZMANN EQUATION

39

The coe⁄cient S is the Seebeck coe⁄cient, often, but somewhat unfortunately, called thermoelectric power: S¼

Ko1 K1 : eT

Using a relation between the integrals K1 and Ko , 2 2 @Ko ðE Þ K 1 ¼ ð kB T Þ 3 @E E¼EF

ð56Þ

ð57Þ

one can write the Seebeck coe⁄cient in the form 8 9 2 ek2B T @Ko ðE Þ 2 k2B T 1 @ðE Þ 2 kB> @ ln ðE Þ : ;kB T S¼ ¼ ¼ > : 3 @E 3e @E E¼EF 3 e @E E¼EF E¼EF ð58Þ The Seebeck coe⁄cient is an important transport parameter and has a considerable bearing on technological applications such as thermocouple sensors and thermoelectric power conversion. The study of thermoelectric phenomena is an interesting topic but clearly beyond the purview of this chapter. A reader interested in thermoelectric e¡ects might ¢nd it useful to consult monographs dedicated to this subject, among them Goldsmid,59 Blatt et al.,60 and Tritt.61 The remaining term in Eqs. (41) and (42) is obtained by setting rT = 0, i.e., imposing isothermal conditions and relating the heat current to the electric current: JQ ¼

Ko1 K1 Je ¼ Je ; e

ð59Þ

where is called the Peltier coe⁄cient. It relates heat generation or absorption in junctions of dissimilar metals to the electric current passed through the circuit. The Peltier e¡ect should not be confused with Joule heating, which is a quadratic function of current and is always dissipative. The Peltier e¡ect is linear in current and is at the heart of an important but niche technology of thermoelectric cooling. The materials of choice are, however, small-gap semiconductors rather than metals. For completeness, we also mention that it follows from Eqs. (56) and (59) that the Seebeck and Peltier e¡ects are closely related, namely ¼ ST : ð60Þ Having de¢ned the transport coe⁄cient and having established its form in terms of the transport integrals, we now address the key issue: the actual mechanism of transport. We will inquire about the dynamics of electrons and about the processes that limit both the electric and heat currents. Since the Wiedemann^Franz law plays such a pivotal role in the theory of transport and in the practical assessment of heat conducting ability of metals, we also inquire about the validity of this law in di¡erent regimes of transport. To address these issues, we rely on a quantummechanical description of the electron motion in a crystalline lattice and on the interactions of electrons with both intrinsic and extrinsic lattice imperfections. We also consider the in£uence of electrons interacting with each other. We should state right at the outset that a theoretical description of the transport mechanism is a di⁄cult and challenging topic. As much as one would like to capture all nuances of the band structure of various metals and make the computations and analysis truly

40

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

metal speci¢c, one soon ¢nds out that the sheer complexity of the problem necessitates various approximations and simpli¢cations that, in spite of valiant e¡orts, yield not much more than a qualitative solution. It is, indeed, unrealistic to expect that the theory will provide perfect agreement with the experimental data. What we hope for are correct predictions regarding the temperature dependence of various transport phenomena, capturing the trends among various classes of metals, and perhaps a factor of 2 consent regarding speci¢c numerical values of the transport coe⁄cients. Because electrical conductivity of metals is so closely tied to their electronic thermal conductivity, we consider its behavior ¢rst. This will serve as an excellent preparation for discussions of heat transport in metals. 3.2. Electrical Conductivity In Eq. (49) we have a basic formula for electrical conductivity. To solve the integral in this equation, we must consider speci¢c models. The most amenable one assumes that electrons are in a band that is strictly parabolic (nearly free electrons). In this case the velocity of electrons at the Fermi surface is simply vðEF Þ = hkF =m* (m* being the e¡ective mass), and the integral over the Fermi surface is 4k2F . Collecting these results, we obtain the electrical conductivity ! ! e2 ðEF Þ 1 hk F e2 ðEF Þ 3 e2 ðEF Þ 2 ne2 ðEF Þ 2 ¼ 4k ¼ k ¼ 3 n ¼ : ð61Þ F h 3 m 43 32 m F 32 m m In Eq. (61) we have recovered a result formally equivalent to the Drude formula, Eq. (9). This time, however, we are on a ¢rm footing in terms of the theory. The relaxation time, which in Eq. (9) was purely a statistical quantity, is now a relaxation time of the electrons on the Fermi surface. Only electrons that are within a thermal layer on the order of kB T of the Fermi energy can respond to an external electric ¢eld because they are the ones that can ¢nd empty states in their vicinity. Electrons deep down in the distribution have no empty states as neighbors and thus are una¡ected. Metals have high conductivity because a relatively small number of themthose in the neighborhood of the Fermi energyhave very high velocities and not because all electrons drift ‘‘sluggishly’’ in response to the electric ¢eld. This is also easily understood from the following illustration that depicts how the out-ofequilibrium electron distribution actually looks. From Eq. (35), taking both gradients rr T and rr EF equal to zero, we write 8 e ðkÞ @f o @E ðkÞ e 9 f ðk Þ ¼ f o ðk Þ :e ¼ f o :k e;; ð62Þ h @E @k h where we used Taylor’s theorem to arrive at the second equality. Eq. (62) states that the steady-state distribution f(k) in reciprocal space (k-space) is the same as the equilibrium distribution that is shifted by ^(e=h)e. Therefore, depicting the equilibrium distribution of electrons by a solid curve in Fig. 1(a), we see that the e¡ect of a constant electric ¢eld applied along the negative x-axis is to shift the entire distribution in the positive x-direction by (e=h) e. The displaced electron distribution is indicated in Fig. 1a by a dashed curve. It is clear from the ¢gure that only electrons near the Fermi edge are a¡ected by the electric ¢eld; electrons lying deep inside the distribution are completely ignorant of the presence of the ¢eld. If the external ¢eld is switched o¡, the steady-state distribution (the dashed curve) will try to relax back to the equilibrium form. The question is, how does the distribution in

Sec. 3

THE BOLTZMANN EQUATION

41

FIGURE 1 Schematic representation of the undisturbed (solid curves) and disturbed (dashed curves) Fermi distributions produced by (a) an electric ¢eld and (b) a temperature gradient. The overpopulated and underpopulated energy levels are marked with + and ^ signs, respectively. Solid and open circles in the upper panels represent the excess and de¢ciency of electrons relative to equilibrium distribution. An electric ¢eld shifts the entire distribution, whereas a temperature gradient creates asymmetry in the distribution function. The reader should note the distinction between the large-angle scattering (the so-called horizontal processes) and small-angle scattering but with a change in the electron’s energy (the vertical processes).

Fig. 1a relax? Obviously electrons must be taken from the region on the right and moved to the opposite side of the Fermi surface. Whether this can be achieved in a single interaction involving a large angular change or whether many smaller steps are needed to bring electrons back determines how e¡ective is the scattering process. The average time needed to reestablish equilibrium is a measure of relaxation time . This may turn out to be a di¡erent time than the average time between successive collisions, o , and we must carefully distinguish these two times. Clearly, if the distribution can be relaxed in a single step, then ¼ o . However, if several collisions are needed to relax the distribution, the time is larger than o and is given by 1 1 ﬃ ð1 hcos iÞ; ð63Þ o where hcos i stands for an average over the scattering angle. The point is that from the perspective of electrical resistivity* it is the change in the electron velocity in the direction of the electric ¢eld which gives rise to resistivity. If each collision changes the direction by only a small amount, many collisions will be needed to accomplish the task of relaxing the distribution. Because the factor (1 - hcos iÞ is sensitive to temperature, it will ¢gure prominently in the discussion of electrical and thermal transport processes considered as a function of temperature. In a strongly degenerate system such as metals the carrier density is essentially *

Thermally perturbed distributions, in addition to a possibility of being relaxed via the mechanism shown in Fig. 1a, i.e., using the so-called horizontal processes, have an alternative and often more e¡ective means of relaxation through very small angle but with a small change in energy, the so-called vertical processes illustrated in Fig. 1b and discussed later.

42

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

temperature independent. It then follows from Eq. (61) that variations in the electrical resistivity with temperature come from the temperature dependence of the relaxation time . With the aid of quantum mechanics, it is, in principle, possible to calculate all scattering probabilities and, therefore, to determine the relaxation time. However, Fermi surfaces of real metals are quite complicated. One either does not have available all the input parameters, or, if one has them, the theory is not capable of incorporating all the ¢ne nuances of the problem. In short, calculations of relaxation times are not a trivial task once one ventures beyond the comfort zone of spherical Fermi surfaces. We have already mentioned that it is somewhat arbitrary to write the collision term in the form given in Eq. (33), and that only in situations where (k) is independent of the external ¢elds is the relaxation time meaningful. Since in this chapter we only consider transport processes in zero magnetic ¢eld, we aim for a relaxation time that is common to both an electric ¢eld and a thermal gradient. Clearly, we would like to know when this is so; i.e., under what conditions does the relaxation time approximation yield a result equivalent to a rigorously calculated collision term in the Boltzmann equation ? This is an important question that touches upon the validity of the Wiedemann^Franz law. It turns out that an electron population disturbed by an electric ¢eld and a thermal gradient will have the same relaxation time when electrons scatter elastically. Actually, as shown in Ref. 2, if the relaxation time approximation returns a solution for the distribution function of the form fðkÞ ¼ f o ðkÞ þ AðE Þ k;

ð64Þ

where a vector quantity A(E) depends on k only through its magnitude, then this solution is rigorous in the sense that the same result is obtained by solving the full Boltzmann equation. We must not forget that by using the relaxation time approximation we have merely introduced the relaxation time as a parameter but we have not solved the scattering problem ; this can be done only by having a general solution to the Boltzmann equation. Tackling such a formidable challenge, one must resort to more sophisticated techniques. Of these, the variational principle has proved to be the most successful. Developed by Ko«hler,62 it is based on the linearized Boltzmann equation for an electric ¢eld and thermal gradient. It de¢nes a function (k) such that @f o f ðk Þ ¼ f o ðk Þ : ð65Þ @E ðkÞ The function is then expressed as a linear combination of appropriately chosen functions with variable coe⁄cients. The aim is to optimize the coe⁄cients so as to produce a trial function that most closely approximates the true solution. The Boltzmann equation is thus reduced to an extremum problem. The better the trial function, the better is the approximation. An interesting upshot of this treatment is its thermodynamic interpretation. One can view the e¡ect of an external electric ¢eld as aligning the velocities of electrons and thus decreasing the entropy. On the other hand, scattering tends to disperse electrons, i.e., decrease the degree of order in the system and thus increase the entropy. The Boltzmann equation therefore expresses a relation between the decrease in entropy (by external ¢elds) and the increase in entropy (by collisions). Since variational calculations test for the max-

Sec. 3

THE BOLTZMANN EQUATION

43

imum, the solution of the Boltzmann equation coincides with the maximum entropy production in the collision processes. For more information on the variational principle as applied to the Boltzmann equation readers might wish to consult Refs. 3 and 63. For completeness, we mention that the Boltzmann equation is not the only plausible approach for the formulation of the transport problem. One may, for instance, use as a starting point linear response theory and derive the conductivity in terms of time correlation functions of current. This is the approach pioneered by Kubo64 and by Greenwood : 65 Z1 1 ¼ hjk ðtÞjl ð0Þidt: ð66Þ kB T 0

Other correlation functions (e.g., force^force correlations66 ) have been tried to arrive at an expression for the conductivity. A di¡erent approach, based on the density matrix formalism, was developed by Kohn and Luttinger.67 Even the optical theorem was explored to derive an expression for conductivity.68 Although these approaches capture the a priori microscopic quantum nature of the problem, none of these delivers a clearly superior solution. Yes, there is considerable comfort and satisfaction that one can start from the fundamentally atomistic perspective and use the rigorous ¢eld-theoretical techniques to arrive at a solution. However, the road to this solution is rather arduous, the treatment is less intuitive, and the results are often di⁄cult to interpret. In spite of its shortcomings and a somewhat less than rigorous nature, the Boltzmann transport equation is not a bad starting point for the theoretical description of transport phenomena. From Eqs. (33) and (61) it follows that the central problem in transport theory is a calculation of the relaxation time . In metals, three main scattering processes a¡ect the electrical and thermal resistivities. (a) electrons can scatter on lattice defects such as foreign atoms (impurities) occupying the lattice sites ; (b) electrons can be de£ected via their interaction with lattice vibrations (phonons); and (c) electrons may interact with other electronsafter all, there are plenty of them around in a metal. We brie£y consider key points on how to proceed in calculating the respective relaxation times for the three scattering scenarios. But ¢rst we mention a remarkable relation known for more than half a century prior to the development of quantum mechanicsMatthiessen’s Rule. This empirical rule, described by Matthiessen in 1862,69 asserts that if several distinct scattering mechanisms are at play the overall resistivity of metals is simply the sum of the resistivities one would obtain if each scattering mechanism alone were present. For example, for two distinct scattering mechanismsscattering on impurities and on lattice vibrationsthe resistivity can be written as 1 m m m ¼ ¼ 2 ¼ 2 þ 2 ¼ ð1Þ þ ð2Þ : ð67Þ ne ne ð1Þ ne ð2Þ The essential point behind Matthiessen’s Rule is the independence of scattering mechanisms; i.e., the overall collision rate is the sum of the collision rates of the participating scattering processes. In the context of the relaxation time approximation this immediately leads to a reciprocal addition of the relaxation times:

44

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

1 1 1 ¼ þ : ð1Þ ð2Þ

ð68Þ

Extensive studies (for a review see Ref. 70) have been done to test the validity of Matthiessen’s Rule. Overall the rule seems to be reasonably robust, with deviations often less than 2%. However, there are situations where the rule breaks down, indicating that the scattering processes are not mutually independent after all. This happens when the relaxation time depends on the k vector ; i.e., ¼ (k). As discussed in Ref. 2, the resistivity is then proportional to a reciprocal average of the relaxation time 1/, and Matthiessen’s Rule implies 1 1 1 ¼ þ : ð69Þ ð1Þ ð2Þ On the other hand, averages performed on Eq. (67) require 1 1 1 ð Þ ¼ ð Þ þ ð Þ: ð1Þ ð2Þ

ð70Þ

The formulas are not equivalent unless ð1Þ and ð2Þ are independent of k. Since there is a small but ¢nite spread of electron wave vectors that can interact with phonons, ð1Þ and ð2Þ are somewhat interdependent and this, in general, leads to an inequality rather than an equality between the total and two partial resistivities : ð71Þ ð1Þ þ ð2Þ : This inequality implies a positive deviation from Matthiessen’s Rule ; i.e., if we write for the total resistivity tot ¼ imp þ ðT Þ, the temperature-dependent resistivity always increases with increasing impurity resistivity imp . This old dogma has been challenged by measurements of Rowlands and Woods,71 who observed negative deviations from Matthiessen’s Rule in samples of Al, Ag, and Pd that were mechanically strained. Thus, it depends on how the resistivity imp is being increased. If the sample is more ‘‘dirty’’ (by stu⁄ng more impurity into it), the deviation will always be positive. If, on the other hand, imp is increased by straining the sample, then the deviation will be negative. The origin of the negative deviations is believed to be electron-dislocation scattering. In mechanically deformed samples electron-dislocation scattering is dramatically enhanced and because this interaction process favors small-angle scattering in contrast to large-angle scattering predominant in the case of electron-impurity scattering, this leads to a reduction of ðT Þ with increasing imp . Although it is not perfectly obeyed, Matthiessen’s Rule gives us a hope of being able to discuss electron scattering in metals in terms of more-or-less independent processes and focus on important characteristics and signatures of each relevant scattering mechanism. Before we do that, let us consider the form of an electron distribution function as it is perturbed by a thermal gradient. 3.3. Electronic Thermal Conductivity An expression for the electronic thermal conductivity is given in Eq. (52). If we do not neglect the term K1 Ko1 K1 with respect to the term K2 , we can write the thermal conductivity as

Sec. 3

THE BOLTZMANN EQUATION

¼

45

1 1 K2 K2 K1 Ko1 K1 ¼ ½K2 eSK1 T ¼ eSK1 ; T T T

ð72Þ

where we used Eq. (56), that de¢nes the Seebeck coe⁄cient S. Forming now a ratio /T (i.e., de¢ning the Lorenz function L), we obtain 8 9 K2 eSK1 K2 SKo1 K1 2 >kB >2 2 L¼ T 2 ¼ 2 2 ¼ : ; S ¼ Lo S 2 ð73Þ T e Ko T e T Ko eT 3 e Thus, the Lorenz function L di¡ers from the Sommerfeld value Lo by a term equal to the square of the Seebeck coe⁄cient. In good metals at ambient temperatures the Seebeck coe⁄cient is a few V/K; i.e., the term S 2 is 1011 V2 /K2 , which is three orders of magnitude smaller than Lo and can be omitted in most situations. Nevertheless, this correction term will be important when we discuss the high-temperature electron^electron contribution to the electronic thermal conductivity of metals. It is instructive to illustrate the electron distribution that arises as a result of the presence of a thermal gradient. In particular, by comparing it with the distribution created by an electric ¢eld, we will be able to highlight the di¡erence between the two and understand why thermal and electrical processes di¡er at low temperatures. From Eq. (35), assuming only a thermal gradient is present, we can write for the distribution function of electrons 98 8 9 @f o >>E > ;: : ;vðkÞðrT Þ ¼ f o ðT þ vðkÞðrT ÞÞ; f ðkÞ ¼ f o ðkÞ þ> ð74Þ @E T where the second equality follows from the use of Taylor’s theorem and the identity 8 9 @f o E > @f o > : ; ¼ ð75Þ @T T @E The distribution is shown in Fig. 1b. We note the following important points: For E > and for vðkÞ ðrT Þ > 0 vðkÞ ðrT Þ < 0

we obtain

f ðkÞ > f o ðkÞ f ðkÞ < f o ðkÞ ð76Þ

For E < and for vðkÞ ðrT Þ > 0 vðkÞ ðrT Þ < 0

we obtain

f ðk Þ < f o ðk Þ f ðk Þ > f o ðk Þ

Therefore, for E > , electrons going in the direction of ^rT (i.e., down the thermal gradient) are hotter and tend to spread the distribution, while electrons going in the direction of rT (i.e., up the thermal gradient) are colder and sharpen the distribution. This is clearly a very di¡erent situation compared to that encountered in Fig. 1a, where the distribution was perturbed by an electric ¢eld with the result that the entire Fermi sphere shifted in response to the applied ¢eld. The nature of the thermal distribution in Fig. 1b presents an alternative mechanism for the electron system to relax. While the electrons may achieve equilibrium by being scattered through large angles across the Fermi surface (the horizontal process e¡ective in relaxing the electron population disturbed by an electric ¢eld in Fig. 1a), in Fig. 1b electrons may relax simply by undergoing collisions in which they

46

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

change their energy by a small amount and move through the Fermi level, but with essentially no change in the wave vector. These types of processesvertical processesprovide a very e¡ective means of relaxing thermally driven distributions and govern thermal conductivity at low temperatures. At high-temperatures (usually including a room temperature) electrons scatter through large angles, the average of cos is zero, and a single collision may relax the distribution. Because scattering through large angles (horizontal processes) becomes less and less probable as the temperature decreases, electrons need many collisions before the direction of their velocity is changed substantially. However, if they can pick up or give up a bit of energy, no such limitation exists and they can relax readily. Thus, we are starting to appreciate that at low temperatures the relaxation time governing electrical conductivity will not be the same as the one governing thermal conductivity. The relaxation time in thermal processes will be considerably shorter because the electrons have an additional and very e¡ective channel through which they can relax the inelastic vertical process. This is the reason why the Wiedemann^Franz law breaks down at low temperaturesthe electrical and thermal processes lack a common relaxation time. 4. SCATTERING PROCESSES Electrons in a solid participate in three main interaction processes : they can scatter on lattice defects, they interact with lattice phonons, and they interact with each other. We have already noted that because of a small but ¢nite spread of electron wave vectors, Matthiessen’s Rule is not perfectly obeyed and interference e¡ects, especially between the impurity and electron^phonon terms, lead to deviations from the rule. Such a slight nonadditive nature of scattering processes arises from the energy dependence of the electron^phonon interaction. As one would expect, deviations from Matthiessen’s Rule also a¡ect the electronic thermal resistivity and, in fact, might be more pronounced there than in the case of electrical resistivity. The reason is that the electrical resistivity is more immune to small changes in the electron wave vector than is the electronic thermal conductivity. Nevertheless, the statement must be quali¢ed in the following sense : (a) As pointed out by Berman,1 deviations from Matthiessen’s Rule are usually largest in the regime where the scattering rates for the electrical and thermal processes di¡er mostat intermediate to low temperatures. Since in this regime phonons are much less e¡ective in limiting electrical resistivity than the electronic thermal resistivity, the fractional in£uence of the same amount of impurity will be larger in the former case. (b) Experimentally, it is far more di⁄cult to design and implement high^precision measurements of thermal conductivity than to do so for electrical resistivity. Thus, while there is no shortage of the data in the literature concerning deviations from Matthiessen’s Rule in electrical resistivity, the corresponding data for the thermal conductivity are rather sparse. We now consider how the di¡erent interaction mechanisms give rise to electrical and thermal resistivities. 4.1. Impurity Scattering Impurities and lattice imperfections are present to a greater or lesser extent in all real crystals, and they are an impediment to the £ow of electrons. Scattering of

Sec. 4

SCATTERING PROCESSES

47

electrons on impurities is especially manifested at low temperatures, where the strength of the competing scattering mechanisms is weaker. In general, impurities are heavy objects on the scale of the electron mass, and, provided the impurity does not have an internal energy structure such that its energy levels would be closely spaced on the scale of kB T , the impurity will not be able to absorb or give energy to a colliding electron. Consequently, impurity scattering is considered a purely elastic event. Since there is no change in the energy of an electron between its initial and ¢nal states, the collision probability Wkk0 is zero unless E(k) = E(k0 ). If U is the interaction potential, ¢rst-order perturbation theory gives for the collision probability : 2 Wkk0 ¼ ½E ðkÞ E ðk0 ÞjhkjUjk0 ij2 : ð77Þ h During linearization of the Boltzmann equation, we invoke the principle of detailed balance, which requires that Wkk0 = Wk0 k . Thus, writing for the number of states of a particular spin in volume V ; V dk/(2Þ3 , simpli¢es Eq. (32) to Z 8 9 @f V > ; ¼ : > dk0 Wkk0 ½f ðk0 Þ f ðkÞ: ð78Þ @t coll ð2Þ3 The terms [1 ^ f(k)] and [1 ^ f(k0 )] fall out and the exclusion principle does not a¡ect the rate of change due to collisions. In order to relate the transition probability Wkk0 to the relaxation time , we must use a formula derived for the modi¢ed distribution function f(r,k,t). The simplest case is that corresponding to an electric ¢eld, and let us say we take it along the x-axis; i.e., @f o f ¼ f o þ e e vx : ð79Þ @E From the de¢nition of (@f=@t)coll we have 8 9 @f fo f @f o > : > ; ¼ ¼ e e vx : @t coll @E

ð80Þ

Substituting for f(k) in Eq. (78), and equating the right-hand side with that of Eq. (80), we get for the relaxation time 8 Z Z 0 9 1 V vx > V m kF > 0 > > ¼ dk Wkk0 :1 ; ¼ jhkjUjk0 ij2 ð1 cos Þ sin d: ð81Þ ð2Þ3 vx 2h3 0

In deriving the second equality in Eq. (81), we use the scattering geometry in Fig. 2. Equation (81) indicates that the scattering frequency is weighted with a factor (1cos Þ. This means that not all scattering processes are equally e¡ective in altering the direction of the electron velocity. Much more weight is given to those processes that scatter electrons through a large angle. Let us consider the case of a static charged impurity of valence Z that occupies a lattice site. The conduction electrons ‘‘feel’’ the presence of this impurity through a screened Coulomb interaction. This arises because the conduction electrons will try to respond to the electric ¢eld of the impurity and will distribute themselves so as to cancel the electric ¢eld at large distances. In the simplest case, modeling the electron gas as a free-particle system, the screened potential has the form of the Yukawa potential:

48

Chap. 1.2

U ðr Þ ¼

THERMAL CONDUCTIVITY OF METALS

Ze2 kT F r e ; 4"o r

ð82Þ

where the parameter kT F is called the Thomas^Fermi screening parameter and its inverse (kT F Þ1 is often referred to as the screening length. The Thomas^Fermi screening parameter is given solely by the electron density and can be written as 9 8 4kF >1=2 > ; ; : kT F ¼ ð83Þ ao where kF is the Fermi wave vector (or momentum) [kF = (32 n)1=3 ] and ao = h2 /me2 = 0.5291010 m is the Bohr radius. For the electron densities in metals, the screening length is on the order of lattice spacing ; i.e., electrons in metals are very e¡ective in screening the electric ¢eld of impurity ions. The matrix element for this potential, , representing electron scattering from a state k to a state k0 is the Fourier transform of the screened potential : Ze2 : hk0 Uimp ki ¼ ð84Þ 2 "o jk k0 j þ k2T F V Substituting this matrix element into Eq. (81), working out the integral, and introducing the density of impurities ni = Ni =V , one obtains for the impurity resistivity, imp : 8 2 9 m 2m ni EF Z 2 > 4k > imp ¼ 2 ¼ F> ð85Þ ;; : 2F> 2 ne 3ne n h k TF

k′

θ

kx α

φ

k FIGURE 2 Scattering con¢guration in three dimensions. The electric ¢eld is assumed to be in the xdirection. Magnitudes of both initial and ¢nal electron wave vectors are kF . A current change results from changes in the electron velocity with respect to the direction of the electric ¢eld. Assuming free electrons, the direction of the electron velocity coincides with the direction of its wave vector. Consequently, after averaging over , the change in the current is given by (kx k0x Þ/kx = 1 ^ v0x /vx = (1-cos Þ.

Sec. 4

SCATTERING PROCESSES

49

where the function F is F ðx Þ ¼

2½lnð1 þ xÞ x=ð1 þ xÞ : x2

ð86Þ

It is of interest to estimate the impurity resistivity per 1% of impurity. As an example, we take copper where the Fermi energy is about 7 eV and the electron density is 8.51028 m3 . Equations (83)^(86) then yield the impurity resistivity contribution of 1.8108 m per 1% of monovalent (Z = 1) impurity. This result is in a reasonable agreement with experimental values (see Table 3), although only two entries (Ag and Au) can be considered monovalent solutes. The scattering cross section calculated with the Born approximation often tends to overestimate the cross section. The partial wave method is considered a better approach. In this scheme a charged impurity represents a spherically symmetric potential for which the Schro«dinger equation has an asymptotic solution of the form 8 9 1 > l > : sin kr ð87Þ þ k;l l ;Pl ðcos Þ: r 2 Here P‘ (cos Þ is a spherical harmonic of order ‘. By matching the functions k;‘ to a plane wave (representing the initial state), one can write for the di¡erential scattering cross section: 2 1 1 X ðÞ ¼ 2 ð2l þ 1Þeil sin l Pl ðcos Þ : ð88Þ k l¼0

TABLE 3 Resistivity increase in Cu per 1 at.% of Solute.a

Impurity

/c (108 m/1 at.%)

Impurity

/c (108 m/1 at.%)

Ag Al As Au B Be Co Fe Ge In

0.14 1.25 6.5 0.53 1.4 0.64 5.8 14.5 3.7 1.2

Mn Ni Pd Pt Sb Se Si Sn V Zn

4.3 1.14 0.84 1.86 5.4 10.6 3.25 2.8 5.8 0.25

a

Data are taken from extensive tables in Landolt-Bo«rstein, New Series.10

50

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

The phase shifts f must satisfy the Friedel sum rule, 2X ð2l þ 1Þl ðkF Þ; Z¼ l

ð89Þ

where Z is the valence di¡erence between the impurity and the solvent metal. It is important to note that static lattice defects (such as charged impurities) scatter all electrons with equal e¡ectiveness; consequently no temperature dependence arises in electrical resistivity due to static lattice defects. This contrasts with phonon transport, where the static defect scattering a¡ects phonons of di¡erent frequencies di¡erently, leading to a temperature dependence. We conclude this section by recapitulating the main points: Because the electrons participating in transport are highly degenerate and are contained within a narrow band of width kB T around the Fermi level, as they encounter a static lattice defect they will scatter elastically. A static lattice defect ‘‘looks’’ the same to all electrons (a very di¡erent situation from that of phonons), and the relaxation time will be temperature independent. Of course, di¡erent static crystalline imperfections (either point imperfections, such as interstitial atoms and vacancies, or extended imperfections, such as dislocations) scatter with di¡erent strength and e¡ectiveness. Relaxation times relevant to each speci¢c situation have been worked out and can be found in the literature.3;72 The essential point concerning all of them is that, in each case, the relaxation time is independent of temperature. Collisions with static imperfections result in a large-enough change in the electron wave vector so that both electrical and thermal processes are a¡ected to the same degree. Electrical resistivity that is given purely by electron scattering on static imperfections is often called the residual impurity resistivity. It is the resistivity that a metal would attain at very low temperatures. The common relaxation time for electrical and thermal transport when electrons scatter on static imperfections means that the Wiedemann^Franz law is valid. From this we glean that the impurity-dominated electronic thermal conductivity will be expected to follow linear temperature dependence and its inversethermal resistivity Wimp will be inversely proportional to temperature: imp Bimp Wimp ðT Þ ¼ ¼ ; ð90Þ Lo T T where Bimp ¼ imp /Lo . 4.2. Electron^Phonon Scattering The most important process that limits the electrical and thermal currents has its origin in a particular kind of a crystal lattice imperfectionthe disturbance of perfect periodicity created by a vibrating lattice ion. Just as an electron scatters when the lattice periodicity is interrupted by the presence of an impurity at a lattice site, the disturbance arising from vibrating ions (phonons in the language of quantum mechanics) leads to a de£ection of an electron from its original path. The major di¡erence between impurity scattering and electron^phonon scattering is that the former represents a purely elastic process, whereas the latter involves emission or absorption of a phonon, i.e., a small but ¢nite change in the electron energy. From a practical perspective, one has some control over the impurity processes because one can, at least in principle, prepare samples of exceptional

Sec. 4

SCATTERING PROCESSES

51

crystalline quality with an exceedingly small amount of impurity in the structure. In contrast, there is nothing one can do about a perturbation created by a vibrating latticeit is there to stay whether we like it or not. The topic of electron^phonon interaction is one of the pillars of solid^state physics. It presents a challenge that requires the full power of a quantum mechanical treatment of the problem. Rather than reproducing a lengthy and complex derivation that can be found in several texts, we will sketch the key steps and give results that are essential in the discussion of electrical and thermal transport in metals. Readers interested in a rigorous treatment of the electron^phonon interaction may ¢nd it useful to consult, among many others, Refs. 3, 5, 63, and 73. In electron^phonon scattering we consider two distinct distributions, those of the electrons and phonons. We know how to treat each one separately^electrons are Bloch waves and obey Fermi^Dirac statistics, and vibrating metal ions show small displacements from their equilibrium positions and thus can be modeled as harmonic oscillators obeying Bose^Einstein statistics. In Chapter 1.1, in the discussion of heat transport by lattice vibrations, it was described how the coupled motions of atoms are transformed to form normal modes, each speci¢ed by its wave vector q and a frequency of vibration !q . These normal modes are quantized as harmonic oscillators, and the energy of a mode with frequency !q is (n + 1/2) h!q , n being an integer. Excitations of the lattice are energy quanta h!q , called phonons. The equilibrium distribution function, i.e., the mean number of thermally excited quanta h!q at a temperature T (the average number of phonons), is given by the Planck distribution function (Bose^Einstein statistics) : 1 N o ¼ h! =k T : ð91Þ q B 1 e If the unit cell contains only one atom, there are only three acoustic modes (branches) of vibrations : one longitudinal with the atomic displacements parallel to the wave vector q, and two transverse, with the displacements perpendicular, to q and to each other. The dependence of the vibrational frequency !q on the wave vector q, !q (q), is called the dispersion relation. In the long-wavelength limit (q !0), !q =vs q, where vs is the speed of sound. If more than one atom resides in the unit cell, more modes arise and they are called optical branches (the number of optical branches is given by 3(p ^ 1), where p is the number of atoms in the unit cell). Optical branches have non^zero frequency at q = 0. The group velocity of a mode, vg = d!q =dq, indicates the speed with which wave packets travel in the crystal and transport thermal energy. Because the optical branches are rather £at, the derivative d!q =dq is quite small, which explains why optical branches are substantially ine¡ective as carriers of heat; thus the task of transporting heat is assigned to acoustic phonon modes. Typical speeds of sound in metals are a few thousand meters per second compared to the speed of sound in air, 340 m/s. In describing the vibrational spectrum of solids, one often relies on the Debye model. A crystal is viewed as consisting of N lattice sites that give rise to 3N acoustic vibrational modes. Moreover, the vibrational spectrum is truncated so that the highest frequency that can be excitedthe Debye frequency !D is given by Z!D Dð!Þd! ¼ 3N: ð92Þ 0

52

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

In Eq. (92) Dð!Þ is the phonon density of states equal to Dð ! Þ ¼

3Vo !2 ; 22 v3s

ð93Þ

where Vo is the sample volume. The question is how to describe the interaction between the electrons and phonons. As pointed out, the feature that distinguishes the electron^phonon interaction from electron-impurity scattering is the quantum of energy h!q that an electron absorbs or emits as it is scattered by a phonon. This is an important constraint because the electron’s energy is changed in the interaction, i.e., the scattering is inelastic. We assume that only one quantum of energy (one phonon) is involved in the scattering process, and therefore the scattering satis¢es the requirement E ðkÞ h! ¼ E ðk0 Þ:

ð94Þ

If the wave vectors of the incoming and outgoing Bloch states are k and k0 , and the phonon wave vector is q, the condition the wave vectors must satisfy (one can view it as a selection rule) is k q ¼ k0 þ G

ð95Þ

where G is a reciprocal lattice vector. Equation (95) delineates two distinct kinds of processes: interactions for which G = 0 are called normal or N-processes ; interactions where a nonzero vector G enters are known as umklapp or U-processes. In essence, Eq. (95) is a statement of the conservation law of momentum (p = hk); in the case of U-processes the vector k + q reaches over the edge of the ¢rst Brillouin zone, and the role of a reciprocal vector G is to bring it back to the ¢rst zone. As Fig. 3 illustrates, U-processes are exceptionally e¡ective in generating resistance because they are capable of nearly reversing the direction of the electron wave vector. Of course, this necessitates a presence of phonons with a certain minimum wave vector which are more plentiful at high, rather than low, temperatures. Therefore, U-processes typically dominate at high-temperatures, and their in£uence weakens exponentially as the temperature decreases. Now, because the lattice ions are much heavier than electrons (M=me 103 Þ, it is assumed that the electrons quickly adjust to changes in the ionic positions. Consequently, within this concept, generally known as the Born^Oppenheimer approximation, the actual electron^phonon interaction is treated as a perturbation on the Bloch states that are calculated under the assumption that the ions are in equilibrium positions. Considering electron^phonon interaction, one might think that the lower^energy cuto¡ (some kind of minimum electrical resistivity) would be given by the zeropoint motion of the lattice ions, i.e., by the term h!(q)/2 being emitted or absorbed by an electron. This, however, would be an incorrect viewpoint. To consider zeropoint motion, we necessarily assume T = 0. But at absolute zero temperature neither phonon absorption nor phonon emission by electrons is possible. Absorption does not happen because nq = 0, and phonon emission cannot take place because an electron would lose energy in such a process. Since at T = 0 the electron gas is perfectly degenerate, there is no available electron state below EF to accommodate the electron.

Sec. 4

SCATTERING PROCESSES

53

T

Nc

*

Nc

N

T N

Tm

Nc

B. Z. a)

b) 0

FIGURE 3 (a) Electron^phonon N-process k+q=k . (b) Electron^phonon U-process k+q=k0 +G, where G is the reciprocal lattice vector. Note a minimum phonon wave vector qm that is necessary for the Uprocess to take place. At low temperatures such wave vectors may not be available.

In order to describe the interaction between an electron and the lattice ions, let us assume that g(k,k0 ,q) is a function that couples the Bloch states k and k0 to the phonon of wave vector q via Eq. (95). We would like to ¢nd out the form of this coupling function, assuming a simple model that neglects any role of U-processes. This is the same simpli¢cation made by Bloch in the derivation of his Bloch^ Gru«neisen formula for the electrical conductivity. Consider an electron situated at point r that ‘‘senses’’ a lattice ion located at point Ri through a potential U(r ^ Ri Þ. The position of the ion Ri can be speci¢ed with respect to its equilibrium position Roi and the displacement Ri . The potential energy of an electron in the ¢eld of all ions of the lattice is the interaction Hamiltonian Heion : X ð96Þ U r Roi þ Ri ; Heion ¼ i

where the summation runs over all ion sites. The potential U[r ^ (Roi +Ri Þ] has an electrostatic origin except that electrons have an excellent ability to screen the longrange tail of the Coulomb potential. One of the simplest forms of screening Thomas^Fermi theoryassumes a slowly varying potential as a function of r given in Eq. (82) together with its screening parameter kT F in Eq. (83). The required smoothness of the potential must be on the scale of a Fermi wavelength, which, stated equivalently, requires q <
i

i

The ¢rst term in the expansion is a constant and represents the potential to which the electrons are subjected when the ions are in their equilibrium lattice positions. This leads to the Bloch description of electrons in the crystalline lattice that we assume anyway. Thus, the electron^phonon interaction is described by the second term in Eq. (97). At this stage one can introduce the phonon coordinates Qq via the displacements Ri :

54

Chap. 1.2

Ri ¼ N 1=2

THERMAL CONDUCTIVITY OF METALS

X q

:

o

eq eiq Ri ; Qq^

ð98Þ

where N is the number of lattice ions in a volume Vo and e“q are unit polarization vectors chosen to be parallel or perpendicular to q when q is along a symmetry direction. From this point, one would usually resort to using the second quantization formalism and express the phonon coordinates in terms of creation and annihilation operators. This is an elegant approach and one that keeps the terms easily tractable. Because not all readers may be familiar with this technique, we shall not follow this road. We simply recognize that we must calculate matrix elements of the form and sum them up for all ions i. The actual computation is given in Ref. 4. As noted, we only consider N-processes. If we further simplify the problem by treating electrons as free electrons (i.e., if we use a plane-wave exp(ik: r)/(Vo Þ1=2 to describe an electron in state k), the coupling function for the electron^phonon interaction becomes a function of q = k0 ^ k only; thus sﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃ ie2 z N h Cq ¼ ð99Þ q:^ eq : 1 þ k2T F =q2 "o q2 Vo 2M!q Here, z is the charge state of an ion, and the subscript is dropped because the polarization is assumed to be either longitudinal or transverse to the wave vector q. We need the square of the modulus of C, which in the long-wavelength limit is 2 2 2 h! q Cq ¼ 2 zEF : ð100Þ 3 q!0 2 3 vs kF Vo M Eq. (100) is usually written in the form 2 Cq ¼ q!0

!q h ; 2N ð0ÞVo

ð101Þ

mkF ; 22 h2

ð102Þ

where N ð0Þ ¼

is the density of states per spin at the Fermi level, and the dimensionless parameter is 8 9 8 9 2z EF2 me 2z EF2 >qD >2 > c >2 me : ; : ; ¼ ¼ : ð103Þ 3 ð kB s Þ 2 M 3 ð kB D Þ 2 kF vs M The temperature s in Eq. (103) is related to the longitudinal sound velocity vs via the equation hkF =kB : ð104Þ s ¼ vs The temperature s de¢ned in Eq. (104) and the Debye temperature D , in terms of which most of the asymptotic forms of the transport formuli and their integration limits are usually stated in the texts, are related by

Sec. 4

SCATTERING PROCESSES

55

TABLE 4 Temperatures s and D Together with the Parameter of Eq. (103) for Selected Metals.a

Metal

s (K)

D (K)

R (K)

(dimensionless)

Na K Cu Ag Al

220 150 490 340 910

150 100 315 215 394

200 114 330 220 395

0.47 0.25 0.16 0.12 0.90

a

Values of s and are from Ref. 4, those of D are from Ref. 74, and R is from Ref. 75.

s vs kF ¼ : D c qD

ð105Þ

Here c is the speed of sound in the Debye model, which is understood to be the average of the long-wavelength phase velocities of all three acoustic modes, not just the longitudinal one vs . Since for free electrons kF = (2/ZÞ1=3 qD , where Z is the nominal valence and qD is the Debye wave vector, s could be larger (perhaps as much as a factor of 2, depending on Z) than the Debye temperature D (see Table 4.). Summarizing the approximations made to obtain the result in Eq. (101), we have: a. Interaction processes were restricted to involve only N-processes b. Thomas^Fermi screening theory was used c. Electrons were treated as free electrons. Such simpli¢cations, of course, have consequences in terms of the validity of the calculation. Even in the simplest of metals (alkali and noble metals), U-processes cannot be completely neglected. Moreover, the coupling constant is appropriate for the long-wavelength limit only and not for phonons of higher frequency. Finally, Fermi surfaces of metals are, in general, quite complicated and electrons are not exactly free electrons. In spite of these limitations, the form of the electron^phonon coupling constant derived is used rather indiscriminately in most calculations. The reason is obvioussuch a treatment yields a rather simple and compact result, and alternative approaches lead to very messy calculations, if possible at all. With the coupling constant given by Eq. (101), one may proceed to calculate the collision integral (@f(k)/@t)coll and inquire about the form of the relaxation time describing the electron^phonon interaction : 8 9 @f 2 X 2 > ; ¼ : > h!q jC j f fk ð1 fk0 Þ 1 þ Nq fk0 ð1 fk ÞNq Ek0 Ek þ @t coll h k0 h!q g: þ fk ð1 fk0 ÞNq fk0 ð1 fk Þ 1 þ Nq Ek0 Ek

ð106Þ

The factors such as fk (1 ^ fk0 Þ enter because of the Pauli exclusion principle, and Nq and Nq stand for phonon distributions under the processes of phonon emission and absorption, respectively. Of course, when both electrons and phonons are in

56

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

equilibrium, the collision term must vanish. When the distributions are disturbed by an electric ¢eld or thermal gradient, the deviations from the equilibrium population can be expressed with the aid of the deviation functions k for electrons and q for phonons: fk ¼ f o þ f o ð1 f o Þ

k0 ;

Nq ¼ N o þ N o ð1 þ N o Þq :

ð107Þ ð108Þ

Computations are considerably simpli¢ed if one makes the following approximation. Provided the phonon^phonon and phonon-impurity scattering processes are very frequent so that they relax the population of phonons e¡ectively, the electron will interact with a phonon that is very close to equilibrium. Hence, one sets the deviation function of phonons to zero. With the identity equation that relates equilibrium distribution functions of electrons and phonons, h!ÞN o ð!Þ ¼ f o ðE þ h!Þ½1 f o ðE Þð1 þ N o ð!ÞÞ; ð109Þ f o ðE Þ½1 f o ðE þ one can linearize Eq. (106). Introducing a relaxation time k , one simpli¢es Eq. (106) to i 1 2 X 2 h ¼ h!q Nqo þ 1 fko0 þ Ek Ek0 þ h!q Nqo þ fko0 : jC j Ek Ek0 k h q ð110Þ The coupling function depends only on the di¡erence between the wave vectors of the outgoing and incoming electrons, q = k0 ^ k. Assuming again that the electrons are described by a free-electron model and converting from summation to integration, we obtain for the high- and low-temperature limits* the following temperature dependences for the electron^phonon relaxation rate: 1=k

/ /

T T

3

for

T D ;

for

T << D :

ð111Þ

The high-temperature resultthe relaxation rate being a linear function of temperaturecould have been anticipated based on a classical argument utilizing equipartition of energy, which is valid since we consider high-temperatures. One would expect the resistance to be proportional to the mean square displacement of an ion in a given direction. An ion of mass M with acceleration d2 x/dt2 is subjected to a restoring force ^bx so as to satisfy the equation M x€ þ bx ¼ 0: ð112Þ Since b=M ¼ !2 = 42 f 2 , where f is the frequency, we can write for the mean potential energy of this oscillator at high-temperatures:

* The Debye temperature qD is the usual upper limit of the summation in Eq. (110) and, thus, the temperature delineating the asymptotic regions of transport. However, this is applicable only for highly degenerate systems such as metals. For semimetals a more appropriate criterion is q =2 kF . Moreover, if the model assumes that electrons couple only to longitudinal phonons, a somewhat higher temperature, such as s in Eq. (104) might be more appropriate.

Sec. 4

SCATTERING PROCESSES

57

1 2 1 bx ¼ kB T : 2 2

ð113Þ

The resistance then becomes R / x2 ¼

kB T kB T h2 T T ¼ 2 2 ¼ 2 / : b 4 f M 4 MkB D M2D

ð114Þ

In order to appreciate what happens to an electron when it interacts with a phonon at high-temperatures, it is instructive to consider the largest possible change in the direction of an electron wave vector in such an electron^phonon encounter. If we assume a free-electron-like monovalent metal (one free electron per lattice ion) consisting of N atoms, the Brillouin zone must accommodate N distinct q-values (modes of vibrations), while the Fermi sphere must be large enough to ¢t (N/2) k-states (N/2 rather than N because each state can have two electrons, one with spin up and one with spin down). Thus, the volume of the Brillouin zone will be twice as large as the volume of the Fermi sphere, which implies that the ratio qD =kF = 21=3 ﬃ 1.26. Therefore, the maximum change in the electron wave vector is k ¼ qD = 1.26kF . From Fig. 4 it follows that the largest possible angle is given by sin(/2) = (q/2)/kF . Inverting this expression, we obtain the maximum scattering angle max = 2 sin1 (q/2kF Þ = 78‡. Of course, this is an idealized case not fully applicable even in alkali metals. Nevertheless, the estimate shows clearly that high-energy phonons (which are plentiful at high-temperatures) can, in a single collision, produce a large change in the direction of an electron with very little change in its energy. Because high-temperature phonons can relax out-of-equilibrium populations of electrons created by either an electric ¢eld or a thermal gradient in a single scattering event, there is one common relaxation time for both electrical and thermal processes. As for the low-temperature limit of Eq. (111), it states that for temperatures well

Nc

kF

θ

N

q D

FIGURE 4 Relationship between the Fermi and Debye spheres for free electrons: qD = 21=3 kF ﬃ 1.26kF . The maximum scattering angle max is given by max = 2 sin1 (qD /2kF Þ ﬃ 78‡.

58

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

below D the electron^phonon scattering rate declines as T 3 . This must not be confused with the rate at which the current density diminishes because the two rates are not the same. What comes into play is the e⁄ciency of scattering. It expresses the fact that, as the temperature decreases, phonon wave vectors become smaller and therefore the scattering angle decreases. Thus, more collisions are needed to make a substantial change in the direction of the electron velocity. We have seen in Eq. (63) that this is taken care of by introducing the e⁄ciency factor (1 ^ cos Þ. From Fig. 4 it follows that 8 9 8 9 8 9 > q >2 1 > q >2 2> > : ; : ; 1 cos ¼ 2 sin ¼2 ¼ : ; : ð115Þ 2 2kF 2 kF hvs , the factor (1 ^ cos Þ introduces a temperature factor T 2 . Because q kB T = Thus, at low temperatures, the electrical resistivity is proportional to T 5 . This result can be derived rigorously by using Kohler’s variational technique to actually solve the Boltzmann equation. We will not reproduce the mathematical derivation, but merely state the ¢nal results. 8 95 8 9 8 95 8 9 1 9h2 C 2 T ne T > : > ; J5 > : > ;¼ A> : > ; J5 > : > ;; ð116Þ ¼ pﬃﬃﬃ 8 2ðm Þ1=2 ea3 MkB D E F 3=2 D T m D T where 9h2 ðm Þ1=2 C 2 A ¼ pﬃﬃﬃ 8 2ne2 a3 MkB D E F 3=2

ð117Þ

=T Z 8 9 > xn ex > Jn : ; ¼ dx: T ðe x 1 Þ2

ð118Þ

and

0

Inverting Eq. (61) and substituting for the relaxation time from Eq. (116), one obtains the famous Bloch^Gru«neisen formula for the electrical resistivity : 76;77 ep ðT Þ ¼

8 95 8 9 m 1 T > ; J5 > : > ;: : > ¼ A 2 ne D T

ð119Þ

We indicate by subscript e-p that the resistivity arises as a result of the electron^ phonon interaction. In most texts such a resistivity is referred to as the ideal resistivityideal in the sense that it would be the resistivity in the absence of impurities (i.e., the resistivity of an ideal solid). Note that di¡erent authors de¢ne the coe⁄cient A di¡erently. Apart from the form of Eq. (117), one often comes across a coe⁄cient that is four times smaller, namely, A0 = A/4. In that case, Eq. (119) is written with a prefactor of 4A0 . It is of interest to look at the asymptotic solutions for low and high-temperatures: 8 95 8 9 T ð =T Þ4 A > T > ; D : > ep ðT Þ ¼ A> ¼ : ; for T D ð120Þ D 4 4 D and

Sec. 4

SCATTERING PROCESSES

59

8 95 T ; for T << D : : > ep ðT Þ ¼ 124:4A> D

ð121Þ

In Eq. (120) we used the approximation Jn ð=T ) ﬃ (/T Þðn1Þ=ðn1Þ , valid for hightemperatures, and in Eq. (121) we substituted J5 ð1Þ = 124.4, applicable at T << D . Thus, at high-temperatures the resistivity is a linear function of temperature, while at low temperatures it should fall very rapidly following a T 5 power law. Note that the T 5 behavior of the resistivity is rarely observed. Apart from the obvious experimental challenges to measure resistivity at low temperatures with a precision high enough to ascertain temperature variations against a now large impurity contribution and a contribution due to electron^electron scattering (see the next section), we should keep in mind the simpli¢cations introduced in the process of calculations, the main ones being spherical Fermi surfaces, N-processes only, Thomas^Fermi approximation, equilibrium phonon distribution. All of these do a¡ect the ¢nal result. It is remarkable that with basically the same approach the theorists are able to calculate an electrical resistivity of even transition metals that agrees with the experimental data to within a factor of 2 (see Table 5). We note that by ¢tting the experimental resistivity data to the Bloch-Gru«neisen formula [Eq. (119)], we can obtain a characteristic temperature R that plays a similar role as D or the characteristic temperature associated with long-wavelength phonons, s . The temperature R is usually much closer to D (see Table 4) than to s , indicating that transverse phonons do play a role in electron scattering. We now turn our attention to a relaxation time relevant to electronic thermal conductivity. This is obtained by performing similar variational calculations to those that led to Eq. (116) except that the trial function is now taken to be proportional to E EF : 8 95 8 9 1 9h2 C 2 T > ; J5 > : > ; : > ¼ pﬃﬃﬃ 2 2ðm Þ1=2 a3 MkB D E F 3=2 D T 9 8 8 9 8 9 3 >kF >2 >D >2 1 J7 ð=T Þ> > > > ; :1 þ 2 : ; : ; 2 qD T 2 J5 ð=T Þ

ð122Þ

TABLE 5 Comparison of Calculated and Experimental Room Temperature Electrical Resistivities of Several Pure Metals.a

Metal

Ag

Au

Cu

Fe

Mo

Nb

Ni

Pd

Ta

W

Experiment Calculation

1.61 1.5

2.2 1.9

1.7 1.9

9.8 11.4

5.3 6.1

14.5 18.4

7.0 5.2

10.5 5.2

13.1 13.2

5.3 7.2

a

Calculated values are from Refs. 78 and 79, and the experimental data are from Ref. 80. Resistivities are in units of 108 m.

60

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

Electronic thermal resistivity arising from electron^phonon interaction (called ideal thermal resistivity) is then 91 1 81 ; : Cv v2F > Wep ðT Þ ¼ ep ¼ > 3 ¼

8 9 8 9 8 9 8 9 A > T >5 > > 3 kF >2 >D >2 1 J7 ð=T Þ : ; J5 : ; 1 þ > : ; : ; Lo T D T 2 qD T 22 J5 ð=T Þ

ð123Þ

where Cv = (2 nk2B /2EF ÞT is the electronic speci¢c heat. The ideal thermal resistivity consists of three distinct contributions. The ¢rst contribution is recognized as having the same functional form as the one in Eq. (119) for electrical conductivity. This term arises from large-angle scattering and, therefore, satis¢es the Wiedemann^Franz law. The second term is due to inelastic small-angle scattering (vertical processes) and has no counterpart in the electrical resistivity. The third term is a correction that accounts for situations where large-angle scattering can reverse the electron direction without actually assisting to restore the distribution back to equilibrium. This is due to the nature of the thermally perturbed distribution function, where an electron can be scattered through large angles between regions having similar deviations (for instance, regions marked + in Fig. 1b). Frequently, asymptotic forms of Eq. (123) are required for low and high-temperatures, and they are 8 9 A 1 >T > ep ðH:T:Þ : ;¼ Wep ðH:T:Þ ¼ for T D ð124Þ 4 Lo T Lo T Wep ðL:T:Þ ¼

¼

8 9 8 9 8 9 8 9 A > T >5 > > 3 >kF >2 >D >2 : ; J5 : ; : ; : ; Lo T D T 2 qD T

8 9 8 9 8 9 8 9 ep ðL:T:Þ 3 >kF >2 >D >2 A >kF >2 > T >2 : ; : ; ¼ 37:8 : ; : ; for T << D : Lo T 2 qD T Lo D qD D

ð125Þ

Equation (124) is just the ¢rst term of Eq. (123) in the limit of high-temperatures. The second and third terms in the square brackets of Eq. (123) are both very small because at high-temperatures J7 =J5 !(1/6)(=T )6 /(1/4)(/T)4 !(2/3)(=T )2 !0. The second equality in this equation follows from using Eq. (120). Thus, at high-temperatures, we expect the ideal electronic thermal resistivity to be temperature independent and, because the relaxation times for the electrical and thermal processes are essentially identical, the Wiedemann^Franz law is obeyed, as Eq. (124) demonstrates. Equation (125) was obtained by considering only the second term in the bracket of Eq. (123) because this term rises rapidly as temperature decreases, while the ¢rst and third terms are constant (1 and 5082/124.4, respectively). The second equality in Eq. (125) is obtained with the aid of Eq. (121). The third equality follows from approximating J5 ðD =T Þ ﬃ J5 ð1Þ = 124.4. We note an important featurethe thermal resistivity at low temperatures follows a quadratic function of temperature and its inverse, the thermal conductivity ep ðT Þ, should be proportional to T 2 . This is indeed what is most frequently observed. Considering all the approximations made, the numerical factors should not be expected to be very precise, perhaps to

Sec. 4

SCATTERING PROCESSES

61

within a factor of 2 or 3. We also observe from Eq. (125) that, at low temperatures, the Wiedemann^Franz law is clearly not obeyed. Writing for the Lorenz ratio L ¼ /T and substituting from Eqs. (119) and (123), we obtain 5 T A D J 5 T L¼ ¼ ¼ 2 2 T W T ep A T 5 D 3 kF 1 J7 ð=T Þ J 1 þ T 5 2 2 L o T D T qD T 2 J5 ð=T Þ ¼

1 þ 32

Lo 2 2 kF D qD

T

Þ 21 2 JJ75 ðð=T =T Þ

:

Asymptotic forms of the ratio L=Lo at high and low temperatures are L ¼ 1 for T D Lo ﬃ

8 98 9 2 >qD >2 > T >2 : ; : ; for T << D : 3 kF D

ð126Þ

ð127Þ

ð128Þ

Equations (127) and (128) state an important result. At high-temperatures, the Lorenz ratio attains its Sommerfeld value Lo . In other words, the relaxation times for electrical conductivity and thermal conductivity are identical, and the Wiedemann^Franz law holds. At these temperatures there are plenty of large^momentum (wave vector) phonons, and they scatter electrons elastically through large angles regardless of whether electron populations are perturbed by an electric ¢eld or a thermal gradient. At low temperatures, a very di¡erent scenario emerges. Here the Lorenz ratio rapidly decreases with decreasing temperatures and the Wiedemann^ Franz law is obviously not obeyed. Phonon wave vectors decrease with temperature and they are incapable of scattering electrons through large angles. Thus, many collisions are necessary to change the velocity of electrons and therefore relax the electron distribution brought out of equilibrium by an electric ¢eld. In contrast, it is much easier to relax a thermally driven disturbance in the electron population. A very e⁄cient route opens whereby electrons just slightly change their energy (inelastic processes) and pass through the thermal layer of width kB T about the Fermi level, and the distribution is relaxed. This means that the relaxation time for thermal processes is considerably shorter than the one for electrical processes. The rate with which the two relaxation times depart as a function of temperature is given by Eq. (126), and a plot of L=Lo as a function of reduced temperature is shown in Fig. 1.10 in Sec. 6. At low temperatures the ratio attains a quadratic function of temperature. The decrease in the Lorenz ratio is particularly large in very pure metals because the temperature range where Eq. (128) is applicable extends to quite low temperatures before any in£uence of impurities is detected. Eventually, at some very low temperature, impurity scattering takes over and, since such processes are essentially elastic, the Lorenz ratio is restored. 4.3. Electron^Electron Scattering Because of their high electron density, one might naively think that the electron^

62

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

electron interaction is a very important component of the electrical and thermal conductivities of metals. Just a rough estimate of the Coulomb energy [e2 /4"o r] of two electrons separated by an interatomic distance comes out to be about 10 eV an enormous amount of energy that exceeds even the Fermi energy. However, this is a very misleading and incorrect estimate. The point is that electrons have an exceptionally good ability to screen charged impurities. We have noted that, in metals, the screening length is typically on the order of an interatomic spacing. This fact, together with the constraints imposed by the Pauli exclusion principle, results in quite a surprising ine¡ectiveness of the electron^electron processes in metals, especially as far as electrical transport is concerned. Interactions among electrons involve four electron states: two initial states that undergo scattering and two states into which the electrons are scattered. It should be clear that if only N-processes (processes in which the total electron momentum is conserved) are involved, the electron^electron interaction on its own would not lead to electrical resistivity because there is no change in the total momentum.* Thus, a possibility for a resistive process in interactions among electrons is tied to the presence of U-processes. But such processes are not too frequent because of the rather stringent conditions imposed by the Pauli exclusion principle. This is readily understood from an argument given in Ref. 2. Here we consider a metal at T=0 with fully occupied states up to the Fermi level and a single electron excited just above the Fermi level. Let us label this electron 1; its energy is E1 > EF . In order for this electron to interact, it must ¢nd a partner from among the electron states lying just below EF because only these states are occupied. We label one such electron 2, and its energy is E2 < EF . The Pauli principle demands that after the interaction the two scattered electrons must go to unoccupied states and these are only available above the Fermi level; i.e., E10 > EF and E20 > EF . Energy in this scattering process must be conserved, 0

0

E1 þ E2 ¼ E 1 þ E 2 ;

ð129Þ

and the wave vectors must satisfy 0

0

k1 þ k2 ¼ k1 þ k2 þ G:

ð130Þ

If E1 is exactly equal toEF , then E2 , E 01 ; and E 02 must also equal EF . Thus, all four states would have to fall on the Fermi surface occupying zero volume in k-space and therefore yielding in¢nite relaxation time at T=0 K. With E1 slightly larger than EF (see Fig. 5), there is a very thin shell of k-space of thickness jE1 EF j around the Fermi level available for ¢nal states E 01 and E 02 . Because only two states (e.g., E2 and E 01 Þ are independent rather than three [E 02 is ¢xed by Eq. (129) once E1 , E2 , and E 01 are chosen], the scattering rate is proportional to (E1 ^ EF Þ2 . If we now assume a ¢nite temperature, the electron distribution will be slightly smeared out (by an amount of thermal energy kB T ), and partially occupied levels will emerge in a shell of width kB T around EF . Since each one of the two independent states now has this enlarged range of width kB T of possible values available, the scattering cross section is reduced by (kB T =EF Þ2 104 at ambient temperature. Thus, at room temperature, the contribution of the electron^electron processes to the transport e¡ects in bulk metals is negligible in comparison to other *

This is strictly correct only for isotropic systems. Any source of anisotropy will give rise to a resistivity contribution associated with N-processes.

Sec. 4

SCATTERING PROCESSES

63

c

ky k1′

k2

k1

kx

k2′

kF

c

FIGURE 5 Schematic of a normal electron^electron interaction. Electrons 1 and 2 with initial wave vectors k1 and k2 scatter from one another to ¢nal states with wave vectors k1 0 and k2 0 . The scattered electrons must go into unoccupied states (i.e., states above the Fermi energy).

scattering mechanisms. If one takes into account static screening, the collision frequency for a purely isotropic electron^electron scattering rate has been evaluated81 and is 8 9 9 1 e 4 ð kB T Þ 2 EF >2 8 > :2kF =kT F;; : ; ¼ 1 þ ð131Þ ee 16h4 "2o kF v3F kB T where

* + 0 0 2 w k1 ; k2 ; k 1 ; k2 1 2 2 2 ðxÞ ¼ V "o kF =e 2 cosð=2Þ ¼

pﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃ x3 x 1 1 p ﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃ tan1 x þ tan x 2 þ x2 : 4 1 þ x2 2 þ x2

ð132Þ

The angular brackets denote an average over a solid angle, which is evaluated explicitly in Ref. 82. The important point for our purposes is the T 2 dependence of the scattering rate. As the temperature decreases, the collision rate diminishes. The T2 variation applies to bulk, three-dimensional metals. If a metallic structure has lower e¡ective dimensionality, a di¡erent temperature dependence results. For instance, for a one-dimensional wire the electron^electron scattering rate is a linear function of temperature

64

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

TABLE 6 Calculated Values of the Coe⁄cient Aee (in units of 1015 m K 2 Þ and the E¡ectivenes Parameter (percent), Together with the Available Experimental values of Aee .a

Metal

rs /ao

Aee (calc)

Aee (calc)/

Aee (exp)

Reference

Li Na K Rb Cs Cu Ag Au Al Pb Fe Co Ni Nb Mo Ru Pd W Re Os Pt Nb3 Sn Bi Graphite

3.25 3.93 4.86 5.2 5.62 2.67 3.02 3.01 2.07 2.3 2.12

2.1 1.4 1.7 3.5 6.7 1.2 1.1 1.9 4.1 16

0.054 0.035 0.021 0.028 0.028 0.35 0.35 0.35 0.4 0.4

40 40 80 130 240 3 3 5 10 40

30 1.9 0.55^4.0

94 95 95^98

0.28^1.21 0.350.15 0.50.2 2.80.2

99^102 100, 103 101 104

310 98 340 23 12.6 27 350 4.8^6.4 45 20 140 70,000 135,000 50,000

105 106 107 108 109 110 111 112 113 113 114 115 116 117

3.07

2.25

80,000

b

a

Also included is the electronic density normalized to the Bohr radius, rs =ao . Values of for alkali metals are from Ref. 91; those for noble metals are from Ref. 92; those for the polyvalent metals are from Ref. 82. The calculated values Aee (calc) include a phonon-mediated correction evaluated in Ref. 91. The theoretical estimate of Aee for Bi and graphite is based on Ref. 93. References are provided for the experimental values of Aee . b

while for a two-dimensional thin metal ¢lm the electron^electron interaction yields a contribution proportional to T 2 ln(TF =T ). Since our ultimate interest is the electronic thermal conductivity, and heat conduction measurements on lower-dimensional systems are exceedingly di⁄cult to carry out, we limit our discussion to bulk metallic systems only. Equation (132) implies a reduction with decreasing temperature of the already weak electron^electron scattering rate. This, however, does not mean that we can completely neglect the in£uence of electron^electron processes. At very low temperatures, where the electron^phonon processes rapidly disappear (ep / T 5 Þ, and in very pure metals, where the impurity resistivity contribution is small, the relatively slow T 2 dependence may propel the electron^electron processes into a position of the dominant scattering mechanism. 4.3.1. Effect of e-e Processes on Electrical Resistivity The earliest experimental evidence for a T 2 term in the resistivity due to electron^ electron interaction is in the data on platinum measured in 1934 by de Haas and de

Sec. 4

SCATTERING PROCESSES

65

Boer.83 Shortly afterward, Landau and Pomeranchuk84 and Baber85 drew attention to the role of electron^electron scattering in the transport properties of metals. Prior to World War II, it was well established that, among the metals, transition elements are the ones that display an identi¢able and measurable T 2 term in their low-temperature resistivity. A textbook explanation why transition metals behave this way was provided by Mott86 in his model based on the sd scattering process. A characteristic feature of transition metals is an incomplete d band with high density of states, in addition to partially ¢lled s and p bands of more or less ordinary (i.e., mobile) electrons. As the s electrons try to respond to an external ¢eld, they scatter preferentially into the high-density d states and acquire the character of the ‘‘sluggish’’ d electrons. This leads to a rather dramatic decrease in the electric current density. Electron^electron scattering of this kind does not even require U-processes; the ordinary N-processes perfectly su⁄ce to generate the large resistivity observed in the transition metals (see Table 1). Because more recent studies indicate that the density of states in transition metals is not that much larger in comparison to the density of states in noble metals, an alternative explanation has been put forward87 to explain the large T 2 term in the resistivity of transition metals. It stresses the importance of a realistic shape for the energy surfaces and the use of the t matrix rather than the Born approximation in calculations of the electron^ electron scattering cross section. Nevertheless, the intuitive appeal of Mott’s picture is hard to deny. In the mid-1970s, following the development of high-sensitivity, SQUID-based detection systems that allowed for an unprecedented voltage resolution in resistivity measurements, major experimental e¡orts con¢rmed that the electron^electron interaction has its unmistakable T 2 imprint on the low-temperature resistivity of most metals (Table 6). Moreover, the interest in electron^electron processes has been hastened by the development of localization theories, and throughout the 1980s much has been learned about electron^electron interaction in lower-dimensional structures. Readers interested in these topics are referred to Kaveh and Wiser.88 Among the outcomes of the intense theoretical e¡ort were two new perspectives on electron^electron scattering in metals. The ¢rst concerns situations where a metal is exceptionally impure, i.e., when the elastic (impurity) mean free path is reduced to a size comparable to the interatomic spacing. In this regime of transport, the usual Fermi liquid theory that is at the core of all our arguments breaks down and must be replaced by a theory that takes into account the e¡ect of disorder on the electron^electron interaction.89;90 Speci¢cally, under the conditions of strong disorder, in addition to the Fermi liquid term T 2 of Eq. (131), there appears a new term 1 ¼ C ð‘e ÞðkB T Þd=2 ; ð133Þ ee where C depends on the mean free path le and d is the dimensionality of the metallic system. Thus, the overall scattering rate due to electron^electron processes in very ‘‘dirty’’ metals is 8 9 8 9 1 1 3 >1=2 > kB >3=2 3=2 : ; : ; T ; ¼ Aee T 2 þ C ð‘e ÞðkB T Þd=2 ¼ Aee T 2 þ > ð134Þ ee 2 EF kF ‘ e where in the second equality the constant Cðle Þ is written explicitly. For reasonably pure metals (kF le >>1) the second term in Eq. (134) is negligible in comparison to

66

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

the ¢rst term. However, for a very impure metal for which the product kF le approaches the Yo¡e^Regel criterion, kF le 1 (near a metal^insulator transition), the second term in Eq. (134) dominates. We shall not consider such highly disordered metals. Rather, we focus our attention on systems that can be treated in the spirit of the Fermi liquid theoryessentially all bulk metals. Therefore, we take it for granted that the scattering rate for electron^electron processes is simply just the ¢rst term in Eq. (134). The second important feature emerged from a rigorous many-body calculation of MacDonald118 and relates to a strong enhancement in the electron^electron collision rate observed in the low-temperature electrical resistivity of metals, which ultimately undergo a transition to a superconducting state. This enhancement arises from the phonon^exchange term in the ‘‘e¡ective’’ electron^electron interaction. The reader may recall that in a conventional picture of superconductivity (the BCS theory) the mechanism of electron pairing is an attractive interaction between electrons via an exchange of virtual phonons. In nonsuperconducting metals (e.g., alkali metals and noble metals) this attractive interaction between electrons is smaller than their Coulomb repulsion. In metals that do superconduct, the attractive interaction is the dominant interaction. This e¡ect leads to a spectacular enhancement (one to two orders of magnitude) in the electron^electron scattering rate of the polyvalent metals such as aluminum or lead. However, at high-temperatures this enhancement is substantially washed out. The limited range of temperatures where the e¡ect shows up implies that one should be cautious when comparing the in£uence of electron^electron processes on the electrical resistivity to its in£uence on the electronic thermal conductivity with the latter accessible only at high-temperatures, as we discuss shortly. With the electron^electron scattering term given by Eq. (131), the electrical resistivity ee and the electronic thermal resistivity Wee (the subscript e-e refers to the electron^electron processes) can be written as ee ðT Þ ¼ Aee T 2

ð135Þ

Wee ¼ Bee T :

ð136Þ

and

The form of Eq. (136) is consistent with the Wiedemann^Franz law, in which case the ratio Aee =Bee plays the role of L. There are indications119 that the value of L for electron^electron processes is close to 1.1108 V2 /K2 . An experimenter faces a daunting task when measuring the coe⁄cients Aee and Bee . Writing for the overall electrical and thermal resistivities* ¼ imp þ ee ðT Þ þ ep ðT Þ; ð137Þ W ¼ Wimp ðT Þ þ Wee ðT Þ þ Wep ðT Þ;

ð138Þ

one must be able to resolve the electron^electron terms against the contributions arising from impurity scattering and from the electron^phonon interaction. Let us

* Depending on what impurities are present in a given metal, there might be additional terms in Eq. (137) representing Kondo-like resistivity and possibly a T-dependent electron-impurity term, which, unlike in Eq. (85), arises due to inelastic scattering.

Sec. 4

SCATTERING PROCESSES

67

illustrate how challenging the task is for the easier of the two casesdetermination of the coe⁄cient Aee . In copper, for example, the impurity resistivity in the purest samples of copper is on the order of 1012 m. Electrical resistivity due to electron^electron processes is on the order of 1016 m at 1 K. Even if one measures the electrical resistivity at very low temperatures (T < 1 K) in order to eliminate a contribution from the electron^phonon scattering, the ratio ee (1 K)/imp 104 . To resolve this with an accuracy of 1%, one is called upon to make precision measurements at the level of one part per million. Such precision was impossible to achieve prior to the development of high-sensitivity SQUID-based voltage detectors (e.g., Ref. 120). However, once these supersensitive devices became available and were incorporated in dilution refrigerators or helium-3 cryostats, a wealth of data appeared in the literature ready to be analyzed. Even in the purest of specimens, one eventually enters a temperature regime where imp becomes the dominant resistive process. Because of its presumed temperature independence, one can eliminate the impurity contribution by simply taking a derivative of Eq. (137) with respect to temperature and isolate the electron^ electron term by writing 1 d 1 dimp 1 dee ðT Þ 1 dep ðT Þ 1 dep ðT Þ ¼ þ þ ¼ Aee þ : ð139Þ 2T dT 2T dT 2T dT 2T dT 2T dT If one now extends measurements to su⁄ciently low temperatures to suppress the electron^phonon term, one obtains Aee . This scheme works well regardless of whether the electron^phonon term is a power law of temperature or, as in the case of alkali metals, an exponentially decreasing contribution on account of a phonon drag e¡ect.121 The values of Aee for transition metals (Table 6) are by far the largest, and thus the data have been collected with relative ease for most transition elements. Interpretation of the data, however, is often complicated by the presence of other interaction mechanisms, most notably electron-magnon scattering which also manifests its presence by a T 2 temperature dependence. It is interesting to compare the coe⁄cients Aee (experimental and theoretical values) for alkali metals with those for noble metals. The data in Table 6 indicate that there is little di¡erence between the two, at least if one focuses on the lighter alkalis. This is a rather fortuitous result. A small value of for alkalis (a few opportunities for U-processes) is compensated by their quite large value of (ee Þ1 =n, resulting in Aee ’s comparable to those of noble metals. One should note that, in some cases, speci¢cally that of potassium and copper, the experimental data are strongly sample dependent. This is indicated by a wide range of values entered in Table 6. As one goes toward polyvalent metals, Aee becomes rather large. Polyvalent metals are often superconductors, and this fact seriously curtails the temperature range where the electron^electron interaction has a chance to be clearly manifested. Frequently, the data are an admixture of electron^electron and electron^phonon interactions, and one must try to separate the two by modeling the behavior of the electron^phonon term. We include in Table 6 a T 2 term for the resistivity of Nb3 Sn, one of the highest Tc conventional superconductors that, close to its transition temperature Tc 18 K, displays a robust quadratic T-dependence of resistivity that extends to about 40 K. While other scattering mechanisms may be at play, it is nevertheless intriguing to consider a proposal by Kaveh and Wiser88 that such a giant T2 term is not inconsistent with

68

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

the electron^electron interaction, especially when one takes into account a strong enhancement in Aee due to phonon mediation. Surely, in this high-transition-temperature conventional superconductor, such an enhancement would be particularly large even though it must disappear at high-temperatures where the resistivity becomes sublinear. There are other features in the transport behavior of these socalled A15 compounds that make Kaveh and Wiser argue that the electron^electron interaction is a reasonable prospect in spite of the controversy such a proposal causes. For completeness we also provide in Table 6 the data on two archetypal semimetals, bismuth and graphite. Low and ultralow-temperature measurements show a quadratic variation of resistivity with temperature. Whether this is a signature of intervalley electron^electronor, more precisely, electron^holescattering93 or a footprint of highly elongated (cigarlike) carrier pockets of electrons on the carrier^ phonon scattering116 has been a puzzle and a source of controversy for some time. If we take a position that electron^hole scattering is important, it cannot be the usual intrapocket variety but rather the interpocket (or intervalley) mechanism. The reason is that the carrier pockets in Bi and graphite are very small (carrier densities are four orders of magnitude lower than in typical metals) and take up only a small fraction of space in the Brillouin zone. The U-processes, the only processes in the case of intravalley scattering that can give rise to resistivity, are simply not accessible in the case of Bi and graphite. On the other hand, interpocket scattering, with or without umklapp processes, is in principle a resistive mechanism, just as the case of sd scattering in transition metals. In compensated semimetals, i.e., systems with an equal number of electrons and holes, even with just N-processes, the interpocket scattering is a highly resistive process.122 This should be evident when one realizes that, in response to an electric ¢eld, electrons and holes move in opposite directions, and thus an interchange of momenta slows down both kinds of carriers. If a semimetal is perfectly compensated, the T 2 dependence of resistivity should be present at all temperatures. In the case of incomplete compensation, the initial T 2 dependence at low temperatures gives way to saturation at high-temperatures. It is important to remember that, within the spirit of the relaxation time approximation, the relaxation time ee in Eq. (131) represents an average of the time between electron^electron collisions over the entire Fermi surface. However, not all collisions are equally e¡ective in hindering the transport, i.e., contributing to the resistivity. We mentioned that N-processes cannot give rise to resistivity. One must therefore somehow capture this notion of ine¡ectiveness of some of the collisions, and this is accomplished by introducing a parameter that measures the fraction of U-processes among all electron^electron processes.82 The parameter plays a similar role as the parameter (1 ^ cos Þit measures the e¡ectiveness of scattering processes in degrading the electrical current. In alkali metals normal electron^electron processes are far more frequent than the U-processes, and thus is very small. In noble metals, and especially in polyvalent metals, the fraction of U-processes drastically rises and rivals that of Nprocesses. This, of course, re£ects the complicated, multisheet Fermi surface providing many more opportunities for U-processes. Hitherto one has to be careful when calculating coe⁄cients Aee . One cannot take a position that all Aee should be roughly the same because all metals have comparable carrier densities and the strength of the electron^electron interaction is approximately the same. The structure and the shape of the Fermi surface really matters, and through the parameter it has a considerable in£uence on the transport properties. Moreover, it depends

Sec. 4

SCATTERING PROCESSES

69

on whether a metal contains isotropic or anisotropic scatterers. The latter situation might lead to a considerable enhancement in Aee at low temperatures if N-processes dominate because the anisotropic electron scattering makes the N-processes resistive.88 4.3.2. Effect of e-e Processes on Thermal Resistivity In the preceding paragraphs we have described a successful approach to determine the electron^electron contribution to electrical resistivity. Of course, one might hope to use the same strategy to evaluate the coe⁄cient Bee of the electron^electron term in the thermal resistivity, Eqs. (136) and (138). Unfortunately, this is not possible, at least not by focusing on the low-temperature transport. The di⁄culty arises not just because now all three terms in Eq. (138) are temperature dependent, W ¼ Bimp T 1 þ Bee T þ Bep T 2 ;

ð140Þ

but, primarily, because the electron^electron contribution is really small and thermal transport measurements do not have a prayer of achieving the desired precision of a few parts per million. To measure thermal gradients (or temperature di¡erences) is a far more challenging task than to measure voltage di¡erences, and the precision one can achieve at low temperatures is at best only about 0.1^1%. So, experimental attempts to isolate and measure Bee at low temperatures are simply futile. However, as shown by Laubitz,123 there is some prospect of accessing and determining Bee via measurements at high-temperatures. Although it is not easy and the utmost care must be exercised to carry the experiments through to their successful conclusion, there is, nevertheless, a chance. The approach is based on an observation that for noble metals the experimentally derived Wiedemann^Franz ratio, Lexp ¼ exp ðT Þ=T Wexp ðT Þ never quite reaches the theoretical Lorenz number Lo = (2 /3)ðkB =eÞ2 , even at temperatures several times the Debye temperature. The essential point here is that Lexp is lower than Lo by a couple of percent as determined by the electronic thermal resistivity only ; i.e., after any, however small, lattice thermal conductivity contribution is subtracted and does not enter consideration. Then, because at high-temperatures (well above the Debye temperature) both impurities and phonons scatter electrons purely elastically, these two scattering processes yield the Sommerfeld value Lo = 2.44108 V2 /K2 for the Lorenz number; i.e., Wimp ðT Þ þ Wep ðT Þ ¼

imp þ ep ðT Þ : T Lo

ð141Þ

To isolate a small term Wee against the background of a very large Wep , one writes, as Laubitz did, the total measured electronic thermal resistivity W exp and electrical resistivity exp as W exp exp W exp ðT Þ exp ðT Þ Aee ¼ ee ee 2 ¼ Bee : ð142Þ 2 T Lo T T Lo T Lo In principle, Eq. (142) allows for a determination of Bee via high-temperature measurements. In reality, because one deals with a very subtle e¡ect, great care is needed to account for any small contribution that we otherwise would have completely neglected. For instance, we take for granted that the Lorenz ratio is

70

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

equal to Lo ¼ =T , while actually, taking into account second-order e¡ects in the thermal conductivity [see Eq. (73)], it should be Lo ^ S 2 , where S is the thermopower. Under normal circumstances we would completely neglect S 2 because in noble metals at ambient temperature it is on the order of 1011 ^1012 V2 /K2 (three to four orders of magnitude less than Lo Þ: Likewise, because the experiment is run at high but ¢nite temperatures and not at T ! 1, there is a remaining ‘‘tail’’ of phonons that scatter electrons inelastically and one should account for it. This is accomplished by introducing a term C=T 2 . Thus, in its practical form, Eq. (142) is written as 9 8 exp C > A ;T : :Bee ee > W exp ðT Þ W exp ¼ þ ð143Þ ðLo S 2 ÞT T 2 Lo Using this approach, Laubitz and his colleagues were able to extract the values of Bee for several alkali, noble, and polyvalent metals. Table 7 lists the experimental results together with a few calculated values. The unusually large probable errors included in the entries in Table 7 should not be surprising, as it is truly a proverbial needle in the haystack type of measurement. The data in Table 7 indicate good agreement between theoretical and experimental values for the alkali metals, whereas calculated values are roughly a factor of 4 larger than the experimental values for noble metals. That Aee and Bee share a common factor (ee Þ1 =n, Aee /

1 ee n

and Bee /

1 ee n

ð144Þ

(the e¡ectiveness parameter enters only in Aee because for the thermal transport all scattering processes hinder heat £ow and thus no is needed) suggests that TABLE 7 Values of the coe⁄cient Bee (exp) Given in Units of 106 mW1 Obtained from HighTemperature Measurements of the Thermal Conductivity and Electrical Resistivity of Several metals.a

Metal

Bee (calc)

Bee (exp)

Reference

Na K Rb Cs

1.1 3.5 4.9 9.0

1.10.6 2.80.5 3.50.5 12.42

34 30 41 125

Cu Ag Au

0.22 0.23 0.29

0.050.02 0.050.02 0.090.03

123 123 123

0.5 <0.04

126 126

Pb Al a

Calculated values of Bee (calc) are from Refs. 115 and 121. The entries for Pb and Al are completely unreliable because they are only an estimate and upper bound, respectively. References relate to the experimental data.

Sec. 4

SCATTERING PROCESSES

71

there is a relationship between Aee and Bee . Indeed, Lawrence and Wilkins82 derived the following relation : 5 Aee ¼ Bee Lo ; ð145Þ 8 þ 3 where Lo = (2 /3)(kB /eÞ2 . This relation in principle provides a consistency check between Aee and Bee . However, there is a major complication that stems from the fact that Aee and Bee are actually temperature dependent, and if a comparison is being made it must be done in the same temperature regimeeither at very hightemperatures or at very low temperatures (but remember, no experimental data are available for Bee at low temperatures). The temperature dependence enters because of two phenomena : phonon mediation in the electron^electron processes, and the in£uence of anisotropic scattering centers such as dislocations. Phonon mediation was introduced by MacDonald118 and by MacDonald and Geldart124 to account for the fact that the overall electron^electron interaction consists of two mutually opposing contributionsthe repulsive Coulomb interaction and the attractive phonon mediated interaction. While the in£uence of phonon mediation di¡ers in di¡erent classes of metals (a very small, 10%, enhancement in noble metals; a factor of 2 decrease in alkali metals; and a huge, more than an order of magnitude, enhancement in polyvalent metals), it is e¡ective only at low temperatures and does not in£uence data at high-temperatures, T > D . Thus, following Kaveh and Wiser88 , we make a sketch of the behavior of Bee ðT Þ as a function of the reduced temperature, T =D (Fig. 6). The electrical resistivity term Aee is subject to the same phonon mediation in£uence. However, because it also depends on the collision e¡ectiveness parameter ,

Al

Bee(T)/Bee( )

10

8

Cu

1 K

0.01

0.1

1

Reduced temperature T/θD FIGURE 6 A plot of the temperature dependence of the coe⁄cient Bee [electron^electron contribution to the electronic thermal resistivity de¢ned in Eq. (136)] normalized to its high-temperature value Bee ð1Þ. The curves represent schematic behavior for a typical alkali metal (K), a typical noble metal (Cu), and a polyvalent metal (Al). [After Kaveh and Wiser in Ref. 88]

72

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

the situation is a bit more complicated. It is well known, and we have indicated so in Table 6, that for some metals (potassium and copper in particular) the literature data on Aee cover a wide range of values. This has nothing to do with the sensitivity or precision of the experimental technique but is due to samples with di¡erent concentration of defects, especially defects such as dislocations that scatter electrons anisotropically. We have pointed out that N-processes are not an impediment to electric current. This is strictly true only if electrons do not encounter anisotropic scattering centers. Since the samples used in the experiments are often annealed at di¡erent temperatures and for di¡erent durations of time, they contain dislocations of usually unspeci¢ed, but certainly unequal, concentrations. A problem with dislocations is that they tend to scatter electrons anisotropically. So, how does this give rise to an additional temperature dependence of Aee ? At low temperatures where impurity scattering dominates, one is de facto in the anisotropic regime if the sample contains a high density of anisotropic scatterers such as dislocations. On the other hand, high-temperature transport is dominated by electron^phonon interactions, and at T D the scattering is essentially isotropic. This qualitatively di¡erent nature of scattering at low and high-temperatures may give rise to an additional (beyond phonon mediation) temperature dependence of Aee . Whether this actually happens depends on a particular class of metals and on the relative importance of normal and umklapp scattering in each speci¢c situation. For instance, in the case of alkali metals, the Fermi surface is essentially spherical and is contained well within the ¢rst Brillouin zone. In such a case, the scattering is dominated by N-processes, the e¡ectiveness parameter is very small, and if only isotropic scattering centers were present the coe⁄cient Aee would vanish or be exceedingly small. However, if alkali metals contain high densities of dislocations, N-processes may turn resistive at low temperatures because scattering of electrons on dislocations is anisotropic. This can lead to a dramatic enhancement in (Aee ÞLT by a few orders of magnitude. On the other hand, if U-processes dominate the scattering events, the e¡ectiveness parameter is large (close to unity), and whether the electrons do or do not encounter dislocations is not going to have an additional substantial in£uence on the already large Aee . Thus, what gives the anisotropic scattering enhancement is the ratio anis (0)/iso (0) taken at low temperatures (marked here as 0 K). The upper bound to the increase in on account of electron-dislocation scattering is in essence given by 1/U , where U is the umklapp electron^electron value of the e¡ectiveness parameter . Large U , i.e., very frequent U-processes, cannot do much for the enhancement, but small U , i.e., the dominance of N-processes, has a great potential for an enhancement if anisotropic scattering centers are present. Kaveh and Wiser127 related the ratio anis (0)/ iso ( 0 ) t o t h e a n i s o t r o p i c o ¼ imp þ disloc ﬃ disloc a n d i s o t r o p i c o ¼ imp þ disloc ﬃ imp limits of scattering. If the preponderance of scattering events involves U-processes, there is no anisotropy enhancement. If, however, scattering is dominated by N-processes, then as the electrons scatter on dislocations they make N-processes resistive and an enhancement is realized. Since the parameter contains information on both umklapp electron^electron and electrondislocation scattering, it follows that if the former one is weak then the electrondislocation scattering can have a great e¡ect on Aee (the case of alkali metals). In the opposite case when U-processes dominate, essentially no enhancement arising from the electron-dislocation scattering is possible. Kaveh and Wiser provide extrapolations for various regimes of dislocation density in di¡erent classes of metals. We conclude this section by sketching in Fig. 7 a possible trend in the temperature

Sec. 5

LATTICE THERMAL CONDUCTIVITY

K

73

"Isotropic limit"

K

100

10

Aee(T)/Aee(∞)

Aee(T)/Aee( )

Al "Anisotropic limit" Al

10

8

Cu

1

Cu

1

0.01

0.1

1

Reduced temperature T/θD

D

0.01

0.1

1

Reduced temperature T/θD

E

FIGURE 7 Temperature dependence of the coe⁄cient Aee [(electron^electron contribution to the electrical resistivity de¢ned in Eq. (135)] normalized to its value at high-temperatures, Aee ð1Þ. (a) The coe⁄cient Aee includes the e¡ect of phonon mediation for a sample in the ‘‘isotropic limit’’, i.e., when the residual resistivity is dominated by isotropic scattering centers. (b) The coe⁄cient Aee in the ‘‘anisotropic limit’’ refers to a situation where scattering is dominated by anisotropic scattering centers. [After Kaveh and Wiser in Ref. 88].

dependence of Aee ðT Þ for representatives of the three main classes of metals we discussed. 5. LATTICE THERMAL CONDUCTIVITY Lattice vibrations are an essential feature of all crystalline solids, regardless of whether they are metals or insulators, and therefore lattice (or phonon) thermal conductivity is always present in any solid material. The question is, how large a fraction of the total thermal conductivity does it represent; in other words, does it dominate the heat conduction process or is it a very small contribution that can be neglected? In Chapter 1.1, heat conduction via lattice vibrations was discussed, and it would seem that we could apply the results found there to the case of metals and have the answer ready. While it is true that phonons will be governed by the relations developed in Chapter 1.1, the problem is that the underlying principles refer primarily to dielectric crystals void of any free charge carriers. In contrast, an environment of metals presents a unique situationon the order of 1023 electrons per cubic centimetersomething that phonons do not encounter in dielectric solids. It is this interaction of phonons with electrons and its in£uence on the phonon thermal conductivity that motivates interest in the study of lattice thermal conductivity in metals. 5.1. Phonon Thermal Resistivity Limited by Electrons The ideal thermal resistivity of metals Wep was discussed in Sect. 4.2. In Eq. (106) we considered the e¡ect of the electron^phonon interaction on the distribution function of electrons. We are now interested in its in£uence on the phonon distribution function Nq . The problem was dealt with ¢rst by Bethe and

74

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

Sommerfeld.128 In the process of changing its state from k to k+q and vice versa, an hq. The collision electron emits or absorbs a phonon of energy h!q with momentum term for this process is 9 8 @N > ; ¼ : q> @t coll

2 2 X Cq 1 fkþq fk Nq ð1 fk Þfkþq Nq þ 1 Ekþq Ek h!q : ð146Þ h k;

The summation now is done over all possible electron states that ful¢ll the energy and wave vector conditions of Eqs. (94) and (95). Retracing the steps taken in deriving Eq. (110), we linearize the collision term using Eqs. (107) and (108) to obtain 9 8 @N > ; ¼ : q> @t coll

2 2 X o Cq f ðEk Þ 1 f o Ekþq N o !q EkþqEkh!q k h k;

kþqþq

: ð147Þ

In deriving the relaxation time k for the ideal electronic thermal conductivity, Eq. (110), we made an assumption that the phonon system is at equilibrium. In the present situation of phonons scattering on electrons, we apply a similar condition, only now we demand that the electron population be at equilibrium, i.e., we set =0. With this simpli¢cation and introduction of a relaxation time for this process, pe , Eq. (147) becomes 1 2 2 X o ¼ Cq f ðEk Þ 1 f o Ekþq Ekþq Ek h!q : ð148Þ pe h k; Substituting for jCq j2 from Eq. (101), integrating over k, and writing the phonon thermal resistivity due to scattering on electrons as Wpe = (pe Þ1 = 3/(Cl v2s pe Þ, where Cl is the lattice speci¢c heat and vs is the longitudinal sound velocity, we obtain 8 92 8 9 T : > ; J3 > : > ;; pe ðT Þ ¼ G> ð149Þ D T where the coe⁄cient G is given by G¼

3 k3B h2D M X 1 : 2 2 3 2 me a j¼1 Cj2

ð150Þ

Here M is the mass of an ion, Cj2 is a coupling constant that speci¢es the interaction between electrons and phonons, and the index j indicates the three possible branches, one longitudinal and two transverse. Equation (149) was originally derived by Makinson.129 Although cast in a di¡erent form, Klemens’ coe⁄cient130 G is identical to Eq. (150). Wilson131 uses a coe⁄cient that is a factor of 3 smaller. Asymptotic forms of Eq. (149) for high and low temperatures are

Sec. 5

LATTICE THERMAL CONDUCTIVITY

pe ðT Þ ﬃ

G ; 2

T ﬃ 7:18G D

75

T D ;

ð151Þ

T << D :

ð152Þ

2 ;

Thus, while at high-temperatures the phonon thermal conductivity due to scattering on electrons is temperature independent, it decreases rapidly at low temperatures; i.e., the electrons are very e¡ective in limiting the heat current due to phonons. At high-temperatures the phonon^phonon umklapp processes are far more e¡ective than electrons in scattering phonons, and the total lattice thermal conductivity never reaches the values indicated in Eq. (151). On the other hand, phonon^electron scattering is an important limiting process for the lattice thermal conductivity of metals at low temperatures, and we shall return to this topic when we discuss thermal conductivity of metals in Sec. 6. Equations (149)^(152) capture the essence of the phonon^electron interaction even though they were developed for a highly simpli¢ed model. We can inquire how the thermal conductivity pe (or thermal resistivity Wpe Þ compares to the ideal thermal conductivity of metals and thus gain some feel for the magnitude of the lattice thermal conductivity and in what temperature range it might have its greatest presence. Using Eqs. (124), (125), (151), and (152), we form a ratio pe /ep for the highand low-temperature range: pe G=2 9C 2 X 1 81 1:03 ¼ ¼ ¼ 2 2¼ 2 for T D ð153Þ 2 2 2 ep 4Lo D =A 8 Na j Cj 8 Na Na 4 7:18 37:81 81 Na 2=3 T 4 4=3 T ¼ 1404 N for T << D : ð154Þ a 2 Na2 2 D D P P In Eqs. (153) and (154) we used [ Cj2 ]1 = [ Cj2 ]/9, assuming that all three polarization branches (one longitudinal and two transverse) interact with the elec2 2 = Ctrans = C 2 /3. P The same assumption was used trons on an equal footing; i.e., Clong P in Ref. 129, except that Makinson apparently took [ Cj2 ]1 = [ Cj2 ]/3. The hightemperature result, Eq. (153), might imply comparable thermal conductivity contributions provided no other scattering processes are present. This, however, is an erroneous assumption since the dominant scattering process for phonons at hightemperatures is not the phonon^electron interaction but U-processes. Their strong presence makes the lattice thermal conductivity in pure metals quite negligible. We also assumed free electrons ; i.e., (qD /kF Þ2 = (2/Na Þ2=3 ; where Na is the number of electrons per metal ion. Turning to the low-temperature ratio, in order for the asymptotic behavior to be valid the ratio D =T should be at least 10. From Eq. (154) it follows that the thermal conductivity pe is much smaller than ep and progressively so as the temperature decreases. Thus, the lattice thermal conductivity will be an insigni¢cant fraction of the total thermal conductivity of pure metals at low temperatures. In fact, in pure metals, the lattice thermal conductivity can safely be neglected except at intermediate temperatures (between the high and low asymptotic regimes), and even there it amounts to no more than about 2%.

¼

76

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

As pointed out, numerical factors in the formulas of transport coe⁄cients re£ect approximations and simpli¢cations necessary to keep the problem tractable. In Eqs. (153) and (154) the situation is compounded by the fact that one is never fully certain exactly how large the contribution of transverse phonons is. The di¡erence 2 2 2 = C 2 , Ctrans = 0) and the Makinson model (Clong = between the Bloch model (Clong 2 2 Ctrans = C /3) is a factor of 3 (actually 9 if properly averaged), and this does not even address the issue of the actual intrinsic strength of the electron^phonon interaction. Thus, one should not be surprised to ¢nd very di¡erent numerical factors used by di¡erent authors when making comparisons such as in Eq. (154). We shall return to this issue in Sec. 6. Although in a cross comparison of the phonon and ideal thermal conductivities we explored a possibility of equal interactions for di¡erent polarizations, the equation that governs the lattice thermal conductivity [Eq. (149)] was derived in the spirit of the Bloch model, assuming that only longitudinal phonons participate in the phonon-electron interaction. If this were so, a contribution of transverse phonons to the low-temperature lattice thermal conductivity of metals would be unchecked and p e would be increasing with decreasing T in a fashion similar to that in dielectric solids. In reality, transverse phonons do contribute to the heat transport. Because of frequent N-processes at low temperatures, there is no reason to assume that a redistribution of the momentum among phonons via three-phonon N-processes somehow discriminates between transverse and longitudinal modes. While normal three-phonon processes do not contribute to the thermal resistance directly, they play an important role in establishing thermal equilibrium because they tend to equalize the mean-free paths of phonons of the same frequency but di¡erent polarization. Thus, in practical situations, transverse phonons are an integral part of the heat transport process and must be considered on equal footing with that of the longitudinal phonons. When metals contain a signi¢cant number of impurities or, for that matter, form alloys, we are presented with a somewhat di¡erent situation than in pure metals. Even though the electronic thermal conductivity remains the dominant contribution, the lattice thermal conductivity may represent a signi¢cant fraction of the overall thermal conductivity and, again, its presence should be most noticeable at intermediate temperatures. Because the defect and impurity scatterings have a much stronger e¡ect on the mean free path of electrons than on phonons, it is primarily the electronic thermal conductivity that decreases. As a result, the lattice thermal conductivity is less a¡ected and attains a proportionally higher in£uence, although rarely exceeding 50% of the electronic contribution. It is only in the case of semimetals (carrier densities of a couple of orders of magnitude lower than in good metals) where the lattice thermal conductivity might dominate at all except at subKelvin temperatures. Experimentally, one has a couple of options for extracting and assessing the lattice thermal conductivity. Because the lattice thermal conductivity contribution in pure metals is very small, it is much easier to work with dilute alloys and extrapolate back to the environment of a pure metal. This is certainly the most accurate, but also the most laborious, approach, necessitating preparation of a series of dilute alloys. The most reliable results are obtained when measuring at low temperatures, say at a liquid helium temperature range. This is usually a lowenough temperature for the defect/impurity scattering to dominate, and the scattering processes are therefore elastic. One can then use the measured electrical resistivity and apply with con¢dence the Wiedemann^Franz law to obtain the electronic

Sec. 5

LATTICE THERMAL CONDUCTIVITY

77

thermal conductivity. The di¡erence between the measured (total) thermal conductivity and the electronic thermal conductivity is the lattice contribution. Performing a series of such measurements on progressively more dilute alloys, one can readily extrapolate the data to zero-impurity content, i.e., to the phonon thermal conductivity of a pure metal. This approach, of course, assumes that there are no dramatic band structure changes within the range of solute concentrations used in the study. Numerous such investigations were done in the late 1950s and throughout the 1960s, a time of very active studies of the transport properties of metals (e.g., Refs. 132^135). In principle, one should also be able to use the same approach at high-temperatures where the scattering of electrons is expected to be elastic. This might work for metals with a rather low Debye temperature, but most of the metals have Debye temperatures (or temperatures s Þ above room temperature, and the usual longitudinal steady-state technique of measuring thermal conductivity is not well suited to temperatures much in excess of 300 K. Thus, one might not be measuring safely within the high-temperature regime (T D Þ, and the scattering processes might not be strictly elastic. Consequently, such measurements would not be as reliable as those performed at low temperatures. What constitutes a safe margin in the context of the high-temperature limit can be gleaned from Fig. 2 in Chapter 1, where the Lorenz ratio, normalized to the Sommerfeld value, is plotted as a function of reduced temperature for di¡erent impurity concentrations in a monovalent metal. One can also estimate (with the same uncertainty as discussed in the preceding paragraph) the magnitude of the lattice thermal conductivity by inspecting how much the Lorenz ratio exceeds the Sommerfeld value Lo . But this is nothing qualitatively new because the Lorenz ratio is not a parameter measured directly but is calculated from the data of the thermal conductivity and electrical resistivity, as described. Also note that electronic and phonon thermal conductivities may be separated with the aid of a transverse magnetic ¢eld. In the context of semiconductors, the phenomenon is often referred to as the Maggi^Righi^Leduc e¡ect. This technique requires very high carrier mobilities, so with a magnetic ¢eld readily available in a laboratory (5^10 T) one can saturate the magnetothermal conductivity and isolate (or more frequently extrapolate toward) the lattice thermal conductivity, presuming it is ¢eld independent. In ordinary metals this approach would not work because the carrier mobility is not high enough and the lattice thermal conductivity is too small. However, in semimetals such as Bi and its isoelectronic alloys the technique works quite well.136 5.2. Other Processes Limiting Phonon Thermal Conductivity in Metals The scattering processes that limit phonon thermal conductivity in metals are primarily U-processes at high-temperatures and phonon^electron scattering at low temperatures. The in£uence of the latter is seen clearly from Eq. (152), which implies that as the temperature decreases the lattice thermal resistivity rises as an inverse square power of temperature. The in£uence of the U-processes can be gleaned from a formula derived by Slack: 137 Up ¼

3 105 Ma a3o 1 ; 2=3 T 2 nc

ð155Þ

78

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

where Ma is the average atomic mass, a is the lattice constant, nc is the number of atoms in a primitive cell, o is the temperature obtained from low-temperature heat capacity, and is the high-temperature Gru«neisen constant. The characteristic 1/T dependence of the lattice thermal conductivity of metals, as well as its magnitude, is quite similar to that of dielectric solids possessing comparable density and shear modulus. Boundary scattering and impurity scattering are considered less e¡ective in the phonon thermal resistivity of metals than in dielectric solids because other processes, notably the phonon^electron and U-processes, are the mean free path-limiting processes. Moreover, point defects do not scatter low-frequency phonons (Rayleigh scattering that governs phonon interaction with point defects has an !4 frequency dependence), and thus the e¡ect of alloying on the phonon thermal conductivity of metals is always much smaller (by a factor of 2^5 for solute concentrations greater than 2 at.%) than the e¡ect of the same solute concentration on the electrical resistivity. Of course, solutes may di¡er regarding their valence state as well as in terms of their mass and size di¡erence vis-a'-vis the solvent atoms. Appropriate treatments for these attributes of impurities are available in the literature.138 In general, the environment of metals is not the best choice for the study of the e¡ect of point defects or boundary scattering on the phonon thermal conductivity; dielectric crystals are far more appropriate for this task. By adding more and more impurity, and especially when the impurity is a strong scatterer of electrons, one may arrive at a situation where the electron mean free path is very short. What constitutes a very short mean free path is conveniently judged by a parameter le q, the product of the electron mean free path with the phonon wave vector. Speci¢cally, electron^phonon interaction as used in transport theory assumes le q >1, which is often interpreted as a condition for an electron to be able to sample all phases of phonons with which it interacts. For very short electron mean free paths, this condition may no longer be satis¢ed. In that case we enter a troublesome regime addressed in the theory of Pippard139 and described in Chapter 1.1. Under these circumstances, the lattice thermal conductivity of metals deviates from T 2 dependence and becomes proportional to a linear function of temperature.140 Of the extended defects, dislocations have been the topic of several investigations (see, e.g. Refs. 141^143). For obvious reasons their in£uence on the lattice thermal conductivity of metals can only be studied in alloys where the lattice thermal conductivity is large enough and one has a chance to resolve its various contributions. However, even in this case the task is challenging because the temperature dependence of phonon-dislocation scattering is proportional to T 2 ; i.e., it has the same functional dependence as phonon-electron scattering at low temperatures.144 One thus has to unambiguously separate the two contributions in order to get a meaningful result. This calls for measurements on a mechanically strained sample that is annealed in stages, taking care that the only e¡ect of annealing is a reduction in the number of dislocations. Of course, one has to somehow independently establish the density of dislocations in order to make the study quantitative. The upshot of such measurements is a seemingly larger number of dislocations (a factor of about 10) required to produce the observed scattering rate,145 1 2 B2 ! / Nd ; str ð!Þ 2

ð156Þ

Sec. 6

THERMAL CONDUCTIVITY OF REAL METALS

79

than what any reasonable and independent estimate of their numbers suggests. In Eq. (156), Nd is the dislocation density and B is the Burgers vector of the dislocation. One can express the strength of dislocation scattering in terms of the increase in the phonon thermal resistivity per dislocation, i.e., Wp d T 2 /Nd . Typical experimental values for Cu 143 are 510 8 cm3 K3 /W, while the improved theory72 yields 510 9 cm3 K3 /W. Thus, it appears that the scattering power of dislocations is about a factor of 10 more than what the theory predicts. However, one must be cautious here because, as pointed out by Ackerman,146 it is not always clear what kind of dislocations are present and what their orientation is. Di¡erent averaging factors may strongly alter the outcome of the analysis. It is interesting, however, that the discrepancy between the actual and implied dislocation densities in metal alloys is signi¢cantly smaller than the discrepancy observed in defected dielectric crystals, where it can reach on the order of 102 ^103 . Finally, we mention that conventional superconductors are perhaps the best system in which to study the in£uence of dislocations in a metallic matrix. The draw here is the fact that well below Tc essentially all electrons have condensed into Cooper pairs, and thus the expected T 2 phonon-dislocation scattering term has no competition from the phonon^electron scattering, because there is none. In this case even pure metals are accessible for the study, and the data exist for Nb, Al, Ta, and Pb,147 149 among others. Invariably, the data indicate exceptionally strong phonon-dislocation scattering that cannot be due to just sessile dislocations but requires a resonant scattering due to vibrating dislocations. 6. THERMAL CONDUCTIVITY OF REAL METALS Having described the relevant interaction processes, we now consider how they in£uence the thermal conductivity of real metals. We should remember that metals present a wide spectrum of band structures that challenge both experimentalists and theorists. They include metals with relatively simple, near-spherically-symmetric Fermi surfaces found in alkali metals and, more or less, noble metals, and extend to a bewildering array of multipiece carrier pockets in polyvalent metals for which spherical symmetry represents a big stretch of the imagination. Thus, it would be very unreasonable to expect that the theoretical predictions developed based on a highly simpli¢ed and ‘‘¢t for all’’^type physical picture could capture the nuances of the physical environment of various metals. We should expect to obtain a pretty good description of transport phenomena in alkalis and noble metals but, for transition metals, rare-earth metals, and polyvalent metals in general, our expectations should be tempered since we might establish no more than general trends. 6.1. Pure Metals Potential problems arise in electrical transport and thermal transport, although in the latter case they seem to be more severe. We mentioned that the Bloch^Gru«neisen T 5 temperature dependence is rarely seen. Even more puzzling is the low-temperature behavior of electrical resistivity of alkali metals where an exponential term is observed at temperatures below 2 K.143 This is caused by a phonon drag contribution arising from an exponentially decaying umklapp scattering term. U-processes no doubt leave their ¢ngerprints on alkali metals also in the form of a rather large value of the electron^electron coe⁄cient Aee (Fig. 7). The neglect of umklapp

80

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

8 ρ

LPS

$

=0

6

$κ / θ

'

4 H

2

0.005

0.02

0.1

0 0.0

0.2

0.4

0.6

0.8

Tθ' FIGURE 8 A plot of the theoretical electronic thermal conductivity versus reduced temperature using the ideal thermal resistivity given in Eq. (123). We assume a monovalent metal, and the parameter imp =A determines the in£uence of impurity scattering. A pronounced minimum near T =D = 0.2 has never been observed in real metals.

scattering indeed seems to be the most serious shortcoming of the theoretical treatment of transport. An excellent example of how the omission of U-processes a¡ects electronic thermal conductivity is provided in Fig. 8, where the theoretical e p [the inverse of We p from Eq. (123), which was derived assuming no participation of Uprocesses] is plotted against the reduced temperature. The curve shows a minimum near D /5 and seems to ‘‘hang’’ at high-temperatures, where it is nearly 60% above the limiting high-temperature ideal thermal conductivity. The minimum is particularly notable when the theory assumes a monovalent metal. Although the minimum is not as pronounced in higher-order calculations of ideal thermal conductivity,150 it takes the participation of U-processes to obliterate it in the theoretical curves. An experimental fact is that such a minimum has never been seen in the thermal conductivity data of monovalent metals. With U-processes properly accounted for, the minimum is a nonissue also in the theoretical description of transport. As an illustration of the trend among the di¡erent classes of metals, we plot in Fig. 9 thermal conductivities for an alkali metal (K), a noble metal (Cu), a transition metal (Ni), and a rare-earth metal (Gd). In each case, the respective curve represents the behavior of a pure metal. If impurities were added, we would see a considerably diminished peak and a gradual shift of its position toward higher temperatures. The curves generally conform to the predictions for thermal conductivity of metals. We note an essentially constant thermal conductivity at high-temperatures giving way to a rapidly rising thermal conductivity at lower temperatures ; a peak developing at low temperatures near T D /15 as a result of the competing in£uence of electron^phonon and electron-impurity scattering ; and, ¢nally, an approximately linear decrease of thermal conductivity with decreasing temperature as impurity scattering dominates the transport. As discussed in Sec. 4.3.2, electron^ electron processes are too weak to be detected in the data of thermal conductivity. The di¡erent magnitudes of thermal conductivity in Fig. 9 are striking, particularly in the case of the transition and rare-earth metals. These two classes of metals

Sec. 6

THERMAL CONDUCTIVITY OF REAL METALS

81

are clearly poor conductors of heat. The low values of thermal conductivity in transition metals and even lower values in rare earths are associated with magnetic interactions and spin disorder. Although not shown here, transition metals and rare earths usually have much more anisotropic thermal properties, due primarily to their anisotropic Fermi surfaces. Because the numerical values of the theoretical transport coe⁄cients serve more as a guide than as hard and reliable numbers, it is often good practice to crosscompare asymptotic forms of the transport coe⁄cients for consistency. With ideal electrical resistivity and ideal electronic thermal resistivity given in Eqs. (120), (121), (124), and (125), and by selecting two temperaturesone in the low-temperature domain TL:T: and one in the high-temperature regime TH:T: (some authors designate this temperature as T = 1Þwe can derive relationships that are expected to hold between various transport coe⁄cients. They are ep ðTL:T: Þ ¼

ð157Þ

95:28 2=3 2 Na TL:T: Wep ðTH:T: Þ; 2D

ð158Þ

95:28 2D Na2=3 ep ðTL:T: Þ: 3 497:6 Lo TL:T:

ð159Þ

Wep ðTL:T: Þ ¼

Wep ðTL:T: Þ ¼

5 497:6 TL:T: ep ðTH:T: Þ; 4 R TH:T:

We have already noted that the domains where the asymptotic forms of the electrical and thermal resistivities (or conductivities) are valid depend on a particular cuto¡ temperature. As ¢rst pointed out by Blackman,151 Bloch theory considers electrons interacting with longitudinal phonons only, and thus the appropriate cuto¡ temperature should be the one related to the longitudinal low-frequency phonons, s . On the other hand, most texts use the Debye temperature, D . Since D is related to a mean of 1/v3 over all polarizations, 9 8 8 9 1 kB >3 4k3B > 1 2 > > > > : ; >; > ¼ ¼ þ ð160Þ h!D 9Nh3 :v3long v3trans ; 3D s is considerably larger than D (typically s 1.5D Þ. The Debye temperature D is normally obtained from the low-temperature speci¢c heat data, where transverse and longitudinal modes, are present. Therefore, the use of D implies the participation of transverse modes in the electron^phonon interaction, and D is the lowest temperature one can justify as a cuto¡. One also has an option to de¢ne the Debyelike temperature R from a ¢t of electrical resistivity by using Eq. (119). In fact, an estimate of this temperature may also be obtained from Eq. (157). The best ¢ts are usually obtained with a cuto¡ temperature that is close to the Debye temperature. This further attests to the importance of transverse phonons to heat transport. There is indeed no reason to assume that transverse phonons would somehow be inactive as far as transport properties are concerned. In principle, the materials that should best conform to a theoretical description are alkali metals. They are monovalent with very nearly spherical Fermi surfaces and, thus, best ¢t the assumptions used in the derivation of Bloch’s transport theory. Consequently, alkali metals had been the center of attention of experimental studies in spite of their high chemical reactivity that complicates sample pre-

82

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

20000 Cu

k (W/m-K)

15000

10000

5000 K Ni

0 Gd

1

10

100

1000

T(K) FIGURE 9 Thermal conductivity plotted as a function of log T (in order to have a better perspective of the position of the maxima) for di¡erent classes of metals, including a noble metal (Cu), an alkali metal (K), a transition metal (Ni), and a rare-earth metal (Gd). The curves are constructed from the data in Refs. 10, 30, 152, 135, 153, 154, respectively. The position of the peaks is at about D /15. The same vertical scale is used for all four metals to emphasize the relative magnitudes of thermal conductivity at low temperatures. Gadolinium has a perfectly developed peak near 25 K, but its thermal conductivity is so low (20 W/m-K at its peak) that on the scale of the ¢gure it looks completely £at.

paration and mounting. Next in the order of complexity are the noble metals that likewise are monovalent but with a Fermi surface that crosses the zone boundary. In these two classes of metals it is reasonable to take the number of electrons per atom, Na , as equal to unity. In gathering experimental data to be used in cross comparisons of transport parameters, it is essential that all transport measurements be made on the same sample and, preferably, using the same contacts. This requires a dedicated e¡ort, and although numerous transport studies have been made during the past 50 years, only a limited set of them conforms to this requirement. Indeed, the most interesting are those related to alkali metals and noble metals. Relevant experimental data for alkali metals and noble metals together with the theoretical predictions based on Eqs. (157)^(159) are presented in Table 8. We note that even for these simplest of metals, signi¢cant disagreements arise between the theory and measurementshigh-temperature (room temperature) experimental data are generally much larger in relation to the low-temperature data than what the theory predicts. Discrepancies seem to be larger for thermal resistivities than electrical resistivities. A part of the problem is no doubt the complexity of calculating ideal thermal resistivity, which, even to lowest order (thermal conductivity is a second-order e¡ect), represents quite an involved computation. Sondheimer150 undertook the challenging task of calculating thermal conductivity to third order and found that the numerical factor in Eq. (158) should be somewhat smaller. Subsequently, Klemens155 solved the Boltzmann integral equation numerically in the limit

Sec. 6

THERMAL CONDUCTIVITY OF REAL METALS

83

T !0 and obtained a further small reduction in the numerical factor. It turns out that the (Bloch^Wilson) coe⁄cient in Eq. (158), the Sondheimer higher-order solution, and the Klemens numerical solution are in the ratio 1.49 : 1.11 : 1.00; i.e., the Klemens solution would yield a factor of 63.95 in place of 95.6 in Eq. (158), and, likewise, the same factor of 95.6 in Eq. (159) should be replaced by 63.95. But such changes are more or less ‘‘cosmetic’’ and do not solve the key problemthe hightemperature theoretical resistivities being too low. Following Klemens,156 the discrepancies are conveniently assessed by using the parameters X and Y which are obtained from Eqs. (158) and (159) by dividing the equations by Wep (TL:T : Þ, substituting the Klemens coe⁄cient 63.95 in place of Bloch’s 95.28, and taking Na = 1: 98 8 9 2 TL:T: Wep ðTH:T: Þ> > > > > > > > X ¼ 63:95: ð161Þ ;: ;; Wep ðTL:T: Þ 2D 98 8 9 2 63:95 2D > TL:T: ep ðTL:T: Þ> > > > > > > Y ¼ ;: : ;: 5 497:6 Lo Wep ðTL:T: Þ TL:T:

ð162Þ

Obviously, theoretical values of X and Y in these equations are equal to unity and as such will serve as a benchmark against which we compare the ‘‘experimental’’ values of X and Y when the respective transport parameters are entered in Eqs. (161) and (162). Before we proceed, it is useful to draw attention to Eqs. (158) and (159) [or to Eqs. (161) and (162)] and point out what is being compared in each case. Equations (158) and (161) relate ideal thermal resistivities at the low- and high-temperature regimes^the same transport parameter but in two very di¡erent transport domains, one dominated by high-frequency phonons, the other by low-frequency phonons. On the other hand, Eqs. (159) or (162) explore a relationship between low-temperature ideal electrical and thermal resistivities, i.e., di¡erent transport coe⁄cients subjected to the in£uence of basically the same low-frequency phonons. The data in Table 8 indicate that for the monovalent metals studied, the values of X and Y are signi¢cantly (in some cases more than an order of magnitude) greater than unity. As far as the parameter X is concerned, this implies that the theoretical ratio Wep (TH:T : Þ/Wep (TL:T : Þ is much smaller than its experimental counterpart. The question is, what is the cause of such a discrepancy ? Since electrons in metals TABLE 8 Transport Parameters of Monovalent Metals.

Metal

[Wep (T)/T2 ]L:T: (W1 mK1 Þ

Wep (TH:T: Þ (W1 mK)

[ep (T)/T5 ]L:T: (mK5 Þ

D (K)

X

Y

Ref.

Na K Rb Cs Cu Ag Au

3.8106 1.2105 9.2105 2.2104 2.6107 6.4107 1.3107

7.3103 7.0103 1.7102 1.7102 2.6103 2.4103 6.4103

5.41017 3.51015 4.51014 6.51013 2.61018 1.11017 3.91017

150 100 60 25 315 215 170

5.3 3.7 3.3 8 6.2 5.2 5.8

1.8 16 9 10 5.4 4.2 4.5

157 158 158 158 159 160 161

84

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

are highly degenerate, apart from a slight ‘‘smearing’’ of the Fermi level at hightemperatures, the electron system itself is substantially temperature independent. This, however, cannot be said about phonons. Because the dominant phonon frequency is proportional to temperature, phonon transport at low temperatures is dominated by long-wavelength phonons (small wave vectors) that reach only a short distance toward the zone boundary. At high temperatures, on the other hand, plenty of phonons with large wave vectors reach very close to the Brillouin zone boundary. This has two important consequences for the high-temperature phonon spectrum that have no counterpart in the low-temperature domain, nor, for that matter, have they been considered in the Bloch^Wilson theory on which Eqs. (158) and (159) are based: a. Phonon dispersion must be taken into account b. U-processes have high probability of occurrence. Phonon dispersion decreases the frequency of large wave vector phonons and increases the high-temperature thermal resistivity. Klemens138 estimates that dispersion could account for up to a factor of 2.3 in the underestimate of the theoretical high-temperature ideal thermal resistivity. Likewise, the participation of U-processes in the high-temperature transport could lead to a comparably large factor. Thus, the bulk of the discrepancy in the parameter X could be eliminated by including the foregoing two modi¢cations to the Bloch^Wilson theory. From the experimental point of view, one should also adjust the data to account for the fact that measurements are carried out under constant pressure whereas the theory assumes conditions of constant volume; i.e., the dimensions of the sample [and therefore all parameters entering Eqs. (158) or (161)] may change slightly due to thermal expansion. One can avoid the di⁄culties with comparing the ideal thermal resistivity across a wide temperature range by using Eq. (159) instead, i.e., focusing on the parameter Y, which relates ideal electrical and thermal resistivities at the same low-temperature regime. As is clear from Table 8, here too one observes serious discrepancies between experiment and theory, with the latter markedly underestimating reality. In this case there is no question of in£uence of dispersion on the phonon spectrum nor of U-processes on the thermal resistivity which is given by vertical processes that are more e⁄cient in impeding heat £ow in this temperature range than horizontal processes. Rather, one must focus on the electrical resistivity and inquire why horizontal scattering processes are so much more e¡ective than the theory would predict. One possible reason might be the participation of transverse ; as well as longitudinal, phonons in the electron^phonon interaction. But we have already taken this into account by using the Debye temperature D as the cuto¡ temperature. Klemens162 proposed an explanation based on the assumption that the Fermi surfaces are not really spherical even in the case of alkali metals. While departures from sphericity have no e¡ect on thermal resistivity because, as mentioned earlier, scattering is governed by the vertical processes that change the energy of electrons but do not substantially alter their direction, nonsphericity may have a strong in£uence on the electrical resistivity. In Sec. 4.2 we pointed out that the relaxation times for electrical and thermal processes at low temperatures are not the same because what matters in relaxing the electron distribution perturbed by an electric ¢eld is the change of the electron momentum (electron wave vector k) away from the direction of the electric ¢eld. At low temperatures only phonons with small

Sec. 6

THERMAL CONDUCTIVITY OF REAL METALS

85

wave vectors q are available to scatter electrons, and it takes many collisions to change the electron momentum by a signi¢cant amountlike taking an electron and moving it across the Fermi surface. Thus, an electron can be viewed as di¡using across the Fermi surface (making many small steps) as it encounters low-q phonons and it interacts with them via N-processes. This is the picture underscoring the Bloch theory. Departures from sphericity, and especially if some segments of the Fermi surface come very close and touch the zone boundary, are going to have a profound e¡ect on the di¡usion process. This creates a great opportunity for Uprocesses to partake in the conduction process at temperatures where they would otherwise have been frozen out had the Fermi surface been spherical. Since such Uprocesses very e¡ectively short out the di¡usion motion of an electron on the Fermi surface, they increase the electrical resistivity. Klemens estimates that the increase could be as much as four times that of the normal di¡usion process, and thus the discrepancies between the theoretical and experimental values of the parameter Y could be explained, at least in the case of noble metals. Of critical importance in the thermal transport of metals is the behavior of the Lorenz ratio. Its magnitude and temperature dependence shed light not only on the nature of scattering of charge carriers, but it also o¡ers a simple and convenient way of assessing how well a given metal conducts heat. Moreover, because thermal conductivity measurements are far more challenging, considerably more expensive to carry out, and much less precise than measurements of electrical resistivity, being able to make use of the resistivity data in conjunction with the knowledge of how the Lorenz ratio behaves also has an economic impact. In Sec. 4.2 we presented a form of the Lorenz ratio that follows from the electron^phonon interaction, Eq. (126). Including a contribution due to impurity scattering, we can write the overall Lorenz ratio as 9 8 95 8 8 9 imp =A þ :T =D ; J5 :D =T ; ; ¼ Lo : ð163Þ L¼: 8 95 8 9 8 92 8 92 WT e imp D ; T; 3 :kF ; :D ; 1 J5 ð=T Þ : : J5 T 1 þ 2 qD 22 A þ D T J7 ð=T Þ At high-temperatures the second and third terms in brackets of Eq. (163) vanish, and the Lorenz ratio equals Lo . At low temperatures the second term representing vertical scattering processes becomes very important and will drive the Lorenz ratio well below Lo (perhaps as much as Lo /2) before the impurity scattering will tend to restore its value back to the Sommerfeld value at the lowest temperatures. Thus, if we have a pure metal, it is quite legitimate to estimate its thermal conductivity at high-temperatures using the high-temperature value of its electrical resistivity in conjunction with the Wiedemann^Franz law and L ¼ Lo . In the case of noble metals the thermal conductivity may be marginally overestimated but by no more than 2%. A similar situation is in the case of alkali metals, except that here the error could approach 10%. The worst-case scenario is the Group IIA metals, Be in particular, and alkaline earths Ba and Sr, where the experimental Lorenz ratio appears anomalously low. Using Lo in place of L might lead to an overestimate of the electronic thermal conductivity by up to 50% for Be and 25%^30% for Sr and Ba, respectively. However, lattice thermal conductivity is a large fraction of heat conduction in Be and alkaline earths, and by neglecting this contribution one e¡ectively compensates for the overestimate of the electronic term. In the case of transition metals, except for Fe and perhaps Os, the experimental Lorenz ratio is

86

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

actually larger than unity, especially for Pd and Pt (25% and 15%, respectively). Yet it is Fe rather than Pd or Pt where the lattice thermal contribution is signi¢cant. Thus, in either case, the calculated value of the thermal conductivity will be underestimated. Large values of L in the case of Pd and Pt were explained to be due to Fermi surface smearing,38 i.e., less than full degeneracy of electrons at hightemperatures. For other pure metals the application of the Wiedemann^Franz law at high-temperatures will not lead to errors larger than about 5%^7%. Compilations of experimental data on the Lorenz ratio of pure metals can be found in Klemens and Williams163 and in Ref. 10. If one is interested in the thermal conductivity of pure metals at temperatures below ambient, one moves away from a comfort zone of essentially elastic electron scattering and one has to deal with the fact that the Lorenz ratio will be governed by Eq. (163). It is instructive to plot the temperature dependence of the Lorenz ratio and note how large reductions in L are likely to arise and at what temperatures they arise (see Fig. 10). Generally, the purer the metal the more dramatic will be the reduction in L. Nevertheless, there are no documented cases where the Lorenz ratio would fall much below about Lo /2 before the impurity scattering at very low temperatures would take over and return the ratio to its Sommerfeld value. Thus, the use of the Wiedemann^Franz law, even in this regime where it is patently invalid, will yield a thermal conductivity that will not be more than a factor of 2 larger than its real value, and such an estimate may often be su⁄cient for technological applications. 6.2. Alloys Depending on what one counts as a metal, there are some 80 metals in the periodic table from which one can make an essentially unlimited number of alloys. It turns out that for industrial applications one virtually always uses alloys because of their mechanical and other advantages over the pure metals. Because it is impossible and impractical to measure thermal conductivity of every one of the alloys one can think of, it would be an advantage to have a simple prescription to assess their thermal conductivities even though the estimates will have a margin of error. 1.00 ρ

LP S

$

= 0.50

0.20

0.75

/ /

R

0.05

0.50 0.01

0.25 ρ

LPS

0.00 0.0

0.2

$

=0

0.4

0.6

0.8

1.0

1.2

Tθ' FIGURE 10 The Lorenz ratio, Eq. (163), plotted as a function of the reduced temperature for progressively higher level of impurity (larger imp =A).

Sec. 7

CONCLUSION

87

In metals with a large concentration of impurities and in alloys, we encounter a situation where electrons are strongly scattered by solute atoms. The immediate consequence is a reduced ability of electrons to carry current and heat, and thus the lattice contribution will have a proportionally larger in£uence on the overall thermal conductivity. Although this complicates the analysis, we have discussed in Sec. 5.1 how one can isolate and estimate the lattice thermal conductivity as well as what the dominant scattering mechanisms are that limit the £ow of phonons. However, large concentrations of impurities and the presence of solute atoms simplify the problem in some sense, at least as far as the electronic thermal conductivity is concernedthey dramatically expand the domain of temperatures where scattering is elastic and thus the Wiedemann^Franz law is valid. Therefore, in numerous situations, a knowledge of the lattice thermal conductivity and the Wiedemann^Franz law is all that one needs in order to assess the heat carrying ability of alloys. In particular, this is the case of high-thermal-conductivity alloys based on Cu, Ag, Au, and Al. Often, thermal conductivity of alloys is described with the aid of the so-called Smith-Palmer equation164 introduced in 1935. It is an empirically based relation between thermal conductivity and the parameter T = ( being electrical resistivity) of the general form Lo T ¼C þ D; ð164Þ where C and D are constants. It assumes a temperature-independent phonon thermal conductivity via the constant D, and thus is suited to situations where pointdefect and/or phonon^electron processes are dominant. As pointed out in Ref. 163, the Smith^Palmer formula seems to ¢t the thermal conductivity data better at hightemperatures (above 500 K) than at lower temperatures. Klemens and Williams163 discuss the relevance of the Smith^Palmer equation to di¡erent industrially useful families of alloys and provide an extensive list of references to the original literature. 7. CONCLUSION Heat conduction in metals is a topic of interest for its intrinsic scienti¢c merit as well as for its relevance to a wide range of technological applications. In this chapter we reviewed the basic physical principles that form the pillars of the transport theory of metals. We tried to present a historical perspective by noting the important developments that have helped to form the understanding of the structure of metals, the energy content of the electron gas, and the key empirical ¢ndings relevant to the transport of charge and heat in metallic systems. We then discussed how the Boltzmann equation addresses the nonequilibrium nature of the electron distribution function created by an electric ¢eld or a thermal gradient. We inquired how the electrons, colliding with the crystal lattice imperfections, establish a steadystate distribution, and how the nature of the conduction process di¡ers in the case of electrical and thermal transport. We considered the three main interaction processes the electrons engage in: scattering on static defects, electron^phonon interaction, and interactions with other electrons. In each case we outlined the main steps leading to a formula for the relaxation time from which we derived expres-

88

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

sions for the electrical and thermal resistivities or their inverseselectrical and thermal conductivities. From the expressions for the electrical and thermal conductivity we derived formulas for one of the most important transport parameters of metalsthe Lorenz ratioand we discussed under what conditions the Wiedemann^Franz law is valid. We stressed that the Wiedemann^Franz law is valid provided that electrons undergo elastic scattering, and we noted that this is the case at high-temperatures (T D Þ where electrons scatter through large angles, and at very low temperatures where impurity scattering dominates the transport behavior. At intermediate temperatures, phonons more e¡ectively impede the £ow of heat than the £ow of electric charge, and the relaxation time for thermal conductivity is considerably shorter than the relaxation time for electrical conductivity. This divergence in the relaxation times invalidates the Wiedemann^ Franz law. Although the £ow of electrons represents the dominant heat conduction mechanism, we considered the contribution of lattice vibrations, and we noted that in most of the pure metals this contribution may be neglected, at least at ambient and very low temperatures. In very impure metals and in alloys this is not the case, and the lattice (phonon) contribution represents a signi¢cant fraction of the overall heat conductivity. We discussed how one can isolate the electronic and lattice thermal conductivity contributions and how one can bene¢t from using the Wiedemann^Franz law in analyzing and assessing heat transport in metals. We supported our text with numerous references to the original research work, and we noted several monographs and review articles that readers might ¢nd useful in pursuing the subject matter in greater detail. We hope that this chapter will serve well to provide a basic understanding about the fascinating and important topic of heat conduction in metals. 8. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20.

R. Berman, Thermal Conduction in Solids (Oxford University Press, 1976). N. W. Ashcroft and N. D. Mermin, Solid State Physics (Saunders, Philadelphia, 1976). J. M. Ziman, Electrons and Phonons (Clarendon Press, Oxford, 1960). H. Smith and H. H. Jensen, Transport Phenomena (Clarendon Press, Oxford, 1989). G. D. Mahan, Many-Particle Physics (Plenum Press, New York, 1990). G. Wiedemann and R. Franz, Ann. Phys. 89, 497^531 (1853). L. Lorenz, Ann. Phys. 13, 422^447 (1881). P. Drude Ann. Phys. 1, 566^613 (1900). J. J. Thomson, Phil. Mag. 44, 293^316 (1897). Landolt-Bo«rnstein, New Series, Vol. 15, edited by O. Madelung (Springer-Verlag, Berlin, 1991). T. Matsumura and M. J. Laubitz, Can. J. Phys. 48, 1499^1503 (1970). J. G. Cook, J. P. Moore, T. Matsumura, and M. P. van der Meer, in Thermal Conductivity 14, edited by P. G. Klemens and T. K. Chu (Plenum Press, New York, 1976), p. 65. M. J. Laubitz and D. L. McElroy, Metrologia 7, 1^15 (1971). J. G. Cook and M. J. Laubitz, Can. J. Phys. 56, 161^174 (1978). G. W. C. Kaye and T. H. Laby, Table of Physical and Chemical Constants (Longmans Green, London, 1966). J. G. Cook and M. J. Laubitz and M. P. van der Meer, Can. J. Phys. 53, 486^497 (1975). L. J. Wittenberg in Proc. 9th Rare Earth Conf., edited by P. E. Field (Virginia Polytechnic Institute, Blacksburg, VA p. 386 (1971). M. J. Laubitz and T. Matsumura, Can. J. Phys. 51, 1247^1256 (1973). J. P. Moore, R. K. Williams and D. L. McElroy, in Thermal Conductivity 7, edited by D. R. Flynn and B. A. Peavy (NBS Spec. Pub. No. 302, Washington, 1968), p. 297. A. W. Lemmon, H. W. Deem, E. A. Eldridge, E. H. Hall, J. Matolich and J. F. Walling, BMI/ NASA Report BATT-4673-T7 (1964).

Sec. 8

REFERENCES

89

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90

Chap. 1.2

THERMAL CONDUCTIVITY OF METALS

A. Matthiessen, Rep. Br. Assoc. 32, 144^150 (1862). J. Bass, Adv. Phys. 21, 431^604 (1972). J. A. Rowlands and S. B. Woods, J. Phys. F 8, 1929^1939 (1978). P. G. Klemens, in Solid State Physics, Vol. 7, edited by F. Seitz and D. Turnbull (Academic Press, New York, 1958), p. 1. 73. A. Haug, Theoretical Solid State Physics, Vol. 2 (Pergamon Press, Oxford, 1972). 74. J. de Launay, in Solid State Physics, Vol. 2, edited by F. Seitz and D. Turnbull, (Academic Press, New York, 1956). 75. F. J. Blatt, in Solid State Physics, Vol. 4, edited by F. Seitz and D. Turnbull (Academic Press, New York, 1957), pp. 199^366. 76. F. Bloch, Z. Phys. 52, 555^600 (1928). 77. E. Gru«neisen, Ann. Phys. Leipzig 16, 530^540 (1933). 78. O. Dreirach, J. Phys. F: Metal Phys. 3, 577^584 (1973) 79. S. N. Khanna and A. Jain, J. Phys. F: Metal Phys. 4, 1982^1986 (1974). 80. G. K. White and S. B. Woods, Can. J. Phys. 33, 58^73 (1955). 81. D. K. Wagner and R. Bowers, Adv. Phys. 27, 651^746 (1978). 82. W. E. Lawrence and J. W. Wilkins, Phys. Rev. B7, 2317^2332 (1973). 83. W. J. de Haas and J. H. de Boer, Physica 1, 609^616 (1934). 84. L. Landau and I. Pomeranchuk, Zh. Eksp. Teor. Fiz. 7, 379^385 (1937). 85. W. G. Baber, Proc. R. Soc. A, 158, 383^396 (1937). 86. N. F. Mott, Proc. Phys. Soc. (London) 47, 571^588 (1935). 87. C. Potter and G. J. Morgan, J. Phys. F 9, 493^503 (1979). 88. M. Kaveh and N. Wiser, Adv. Phys. 33, 257^372 (1984). 89. A. Schmid, Z. Phys. 271, 251^256 (1974). 90. B. L. Altshuler, A. G. Aronov and P. A. Lee, Phys. Rev. Lett. 44, 1288^1291 (1980). 91. A. H. MacDonald, R. Taylor and D. J. W. Geldart, Phys. Rev. B 23, 2718^2730 (1981). 92. J. E. Black, Can. J. Phys. 56, 708^714 (1978). 93. C. A. Kukkonen and P. F. Maldague, J. Phys. F: Metal Phys. 6, L301^302 (1976). 94. M. Sinvani, A. J. Greenfield, M. Danino, M. Kaveh and N. Wiser, J. Phys. F:Metal Phys. 11, L73^78 (1981). 95. B. Levy, M. Sinvani, and A. J. Greenfield, Phys. Rev. Lett. 43, 1822^1825 (1979). 96. H. van Kempen, J. S. Lass, J. H. Ribot and P. Wyder, Proc. 14th Int. Conf. on Low Temperature Physics, Vol. 3, Amsterdam; (North-Holland, 1976), pp. 94^97. 97. J. A. Rowlands, C. Duvvury and S. B. Woods, Phys. Rev. Lett. 40, 1201^1204 (1978). 98. C. W. Lee, M. L. Hearle, V. Heinen, J. Bass, W. P. Pratt, J. A. Rowlands and P. Schroeder, Phys. Rev. B 25, 1411^1414 (1982). 99. B. R. Barnard and A. D. Caplin, Commun. Phys. 2, 223^227 (1977). 100. M. Khoshnevisan, W. P. Jr. Pratt, P. A. Schroeder S. Steenwyk and C. Uher, J. Phys. F 9, L1^ L5 (1979). 101. E. Borchi and S. de Gennaro, J. Phys. F 10, L271^L274 (1980). 102. A. Bergmann, M. Kaveh and N. Wiser, J. Phys. F 12, 2985^3008 (1982). 103. M. Khoshnevisan, W. P. Jr. Pratt, P. A. Schroeder, S. Steenwyk, Phys. Rev. B 19, 3873^3878 (1979). 104. J. H. Ribot, J. Bass, F. van Kempen, R. J. M. van Vucht and P. Wyder, J. Phys. F 9, L117^122 (1979). 105. J. G. Beichtman, C. W. Trussel and R. V. Coleman, Phys. Rev. Lett. 25, 1291^1294 (1970). 106. D. Radhakrishma and M. Nielsen, Phys. Stat. Solidi 11, 111^115 (1965). 107. G. K. White and R. J. Tainsh, Phys. Rev. Lett. 19, 165^166 (1967). 108. G. W. Webb, Phys. Rev. 181, 1127^1135 (1969). 109. T. L. Ruthruff, C. G. Grenier and R. G. Goodrich, Phys. Rev. B 17, 3070^3073 (1973). 110. J. T. Schriempf and W. M. MacInnes, Phys. Lett. A 33, 511^512 (1970). 111. C. Uher and P. A. Schroeder, J. Phys. F: Metal Phys. 8, 865^871 (1978). 112. C. Uher M. Khoshnevisan, W. P. Pratt, and J. Bass, J. Low. Temp. Phys. 36, 539^566 (1979). 113. J. T. Schriempf, Solid State Commun. 6, 873^876 (1968). 114. C. Uher, C. W. Lee and J. Bass,, Phys. Lett. A61, 344^346 (1977). 115. G. W. Webb, Z. Fisk, J. J. Engelhardt and S. D. Bader, Phys. Rev. B 15, 2624^2629 (1977). 116. C. Uher and W. P. Pratt, Phys. Rev. Lett. 39, 491^494 (1977). 117. D. T. Morelli and C. Uher Phys. Rev. B 30, 1080^1082 (1984). 118. A. H. MacDonald, Phys. Rev. Lett. 44, 489^493 (1980). 69. 70. 71. 72.

Sec. 8

REFERENCES

91

119. C. Herring, Phys. Rev. Lett. 19, 167^168 (1967). 120. W. P. Pratt, C. Uher, P. A. Schroeder and J. Bass, in Thermoelectricity in Metallic Conductors, edited by F. J. Blatt and P. A. Schroeder (Plenum Press, New York, 1978), pp. 265^280. 121. M. Kaveh and N. Wiser, Phys. Rev. Lett. 26, 635^636 (1971). 122. P. F. Maldague and C. A. Kukkonen, Phys. Rev. B 19, 6172^6185 (1979). 123. M. J. Laubitz, Phys. Rev. B 2, 2252^2254 (1970). 124. A. H. MacDonald and D. J. W. Geldart, J. Phys. F 10, 677^692 (1980). 125. J. G. Cook, Can. J. Phys. 60, 1759^1769 (1982). 126. M. J. Laubitz and J. G. Cook, Phys. Rev. B 7, 2867^2869 (1973). 127. M. Kaveh and N. Wiser, Phys. Rev. B 21, 2291^2308 (1980). 128. A. Sommerfeld and H. Bethe, in Handbuch der Physik, Vol. 24, Part 2 (Springer, Berlin, 1933), p. 33. 129. R. E. B. Makinson, Proc. Camb. Phil. Soc. 34, 474^497 (1938). 130. P. G. Klemens, Aust. J. Phys. 7, 57^63 (1954). 131. A. H. Wilson, Theory of Metals (Cambridge University Press, 1958). 132. W. R. Kemp, P. G. Klemens, R. J. Tainsh and G. K. White, Acta Metall. 5, 303^309 (1957). 133. G. K. White and R. J. Tainsh, Phys. Rev. 119, 1869^1871 (1960). 134. D. Greig and J. P. Harrison, Phil. Mag. 12, 71^79 (1965). 135. T. Farrell and D. Greig, J. Phys. C 2, 1465^1473 (1969). 136. C. Uher and H. J. Goldsmid, Phys. Stat. Solidi (b) 65, 765^772 (1974). 137. G. A. Slack, in Solid State Physics, Vol. 34, edited by H. Ehrenreich, F. Seitz and D. Turnbull (Academic Press, New York, 1979), pp. 1^71. 138. P. G. Klemens, in Encyclopedia of Physics, Vol. 14, edited by S. Flu«gge (Springer-Verlag, Berlin, 1956), pp. 198^218. 139. A. B. Pippard, Phil. Mag. 46, 1104^1114 (1955). 140. P. Lindenfeld and W. B. Pennebaker, Phys. Rev. 127, 1881^1889 (1962). 141. J. N. Lomer and N. H. Rosenberg, Phil. Mag. 4, 467^483 (1959). 142. P. Charsley, J. A. M. Salter and D. W. Leaver, Phys. Stat. Solidi 25, 531^540 (1968). 143. W. R. G. Kemp, P. G. Klemens and R. J. Tainsh, Phil. Mag. 4, 845^857 (1959). 144. W. R. G. Kemp and P. Klemens, Aust. J. Phys. 13, 247^254 (1960). 145. F. R. N. Nabarro, Proc. R. Soc. A209, 278^290 (1951). 146. M. W. Ackerman, Phys. Rev. B5, 2751^2754 (1972). 147. A. C. Anderson and S. C. Smith, J. Phys. Chem. Solids, 34, 111^122 (1973). 148. S. G. O’Hara and A. C. Anderson, Phys. Rev. B9, 3730^3734 (1974). 149. S. G. O’Hara and A. C. Anderson, Phys. Rev. B10, 574^579 (1974). 150. E. H. Sondheimer, Proc. Roy. Soc. A203, 75^98 (1950). 151. M. Blackman, Proc. Phys. Soc. London A64, 681^690 (1951). 152. R. S. Newrock and B. W. Maxfield, Phys. Rev. B7, 1283^1295 (1973). 153. L. Binkele, High Temp.-High Pressures 18, 599^607 (1986). 154. W. J. Nellis and S. Legvold, Phys. Rev. 180, 581^590 (1969). 155. P. G. Klemens, Aust. J. Phys. 7, 64^69 (1954). 156. P. G. Klemens, Aust. J. Phys. 7, 70^76 (1954). 157. R. Berman and D. K. C. MacDonald, Proc. R. Soc. London A209, 368^375 (1951). 158. D. K. C. MacDonald, G. K. White and S. B. Woods, Proc. R. Soc. London A235, 358^374 (1956). 159. R. Berman and D. K. C. MacDonald, Proc. R. Soc. London, A211, 122^128 (1952). 160. K. Mendelssohn and M. H. Rosenberg, Proc. Phys. Soc. London A65, 385^388 (1952). 161. G. K. White, Proc. Phys. Soc. London A66, 559^564 (1953). 162. P. G. Klemens, Proc. Phys. Soc. London A67, 194^196 (1954). 163. P. G. Klemens and R. K. Williams, Int. Metals Rev. 31, 197^215 (1986) 164. C. S. Smith and E. W. Palmer, Trans. AIME 117, 225^243 (1935).

Chapter 1.3

THERMAL CONDUCTIVITY OF INSULATORS AND GLASSES Vladimir Murashov and Mary Anne White Department of Chemistry and Institute for Research in Materials Dalhousie University, Halifax, Nova Scotia, Canada

1. INTRODUCTION Heat transport in a system is governed by the motion of ‘‘free particles’’ which try to restore thermodynamic equilibrium in the system subjected to a temperature gradient. For insulating materials we can generally ignore contributions of mobile electrons to thermal conduction processes, which dominate the thermal conductivity of metals, and concentrate instead on propagation of heat through acoustic phonons.1 In general, we begin with the concept of a perfect harmonic solid (i.e., one in which all interactions are well represented by harmonic oscillators) being a perfect carrier to heat (i.e. with an in¢nite thermal conductivity, ). Since this is not the case for any insulating material under any circumstances, we seek to understand thermal conductivity in terms of thermal resistance mechanisms. In this chapter we present theories of thermal conductivity of insulating materials and glasses, and, where useful to illustrate the theories, some experimental ¢ndings. Experimental data for some 400 insulating solids have been compiled, and they were published in 1970.2 Although the thermal conductivities of many more substances have been determined since then, no thorough updated compilation has been published. Several reviews of thermal conductivity of nonmetallic solids and of glasses have been published previously. 3 6 Our discussion starts with the most ordered simple solids, adding degrees of disorder until we ¢nish with a discussion of the thermal conductivity of glasses. All the while, we should keep in mind that, generally, thermal conductivity is an anisotropic property and that, furthermore, most theories apply to isochoric conditions, whereas most experiments are carried out isobarically. (Ross and co-work-

94

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THERMAL CONDUCTIVITY OF INSULATORS AND GLASSES

ers4; 5; 7 have shown the importance of this correction, especially for soft or disordered solids; for example, it changes by 30% for adamantane at room temperature, although the e¡ect is much smaller at low temperatures.5 ) 2. PHONONIC THERMAL CONDUCTIVITY IN SIMPLE, CRYSTALLINE INSULATORS 2.1. Acoustic Phonons Carry Heat The common approach to understanding thermal conductivity of simple, crystalline dielectric solids is based on Debye’s equation for heat transfer in gases, treating the lattice vibrations as a ‘‘gas’’ of phonons: 8; 9 1 ¼ Cv; ð1Þ 3 where C is the heat capacity per unit volume, v is the average phonon group velocity, and is the mean free path of phonons between collisions. For a more general anisotropic case, elements of the thermal conductivity tensor can be expressed as a sum over all wave vectors, k, of the ¢rst Brillouin zone for each polarization branch, m: 10 X ij ¼ v1 ðk Þ vj ðk Þ j ðkÞ C mðkÞ; ð2Þ k;m

where is the phonon relaxation time. The contribution of the optic branches of the dispersion curve to the heat capacity at constant volume, Cv , is approximated by the Einstein model of isolated atomic vibrations.11 (See Chapter 1.1.) Phonons from the optic branches usually are ine¡ective carriers of thermal energy, but, as we shall show, they can attenuate heat £ux by the acoustic modes in certain circumstances, especially for more complex insulators. However, most of the thermal energy in insulators is carried by acoustic phonons.12 The Debye approximation of lattice dynamics as collective vibrations of atoms gives a good estimate of the acoustic contribution to the heat capacity (see also Chapter 1.1): 8;9 Zx x 4 ex 3 dx; ð3Þ C ¼ 9N kB x ðex 1 Þ2 0

where x ¼ D /T , D (= hD /kB Þ is the Debye (characteristic) temperature, and D is the Debye cuto¡ frequency. The heat capacity of a solid with n atoms per unit cell is best represented by three Debye (acoustic) modes and (3n ^ 3) Einstein (optic) modes. Although the heat capacity of an insulating solid can be modeled to within a few percent if the mode frequencies are well known from vibrational experiments, the models for thermal conductivity are much less quantitatively advanced. Resistance to heat £ow in dielectric solids (or, in other words, interference to phonon motion) arises from scattering of phonons by defects in the crystal structure (lattice defects, grain boundaries, isotopes, impurities, etc.) and from collisions of phonons with each other, resulting in an alteration of phonon frequencies and momenta. In the (ideal) harmonic solid, such phonon^phonon interactions are not

Sec. 2 LATORS

PHONONIC THERMAL CONDUCTIVITY IN SIMPLE, CRYSTALLINE INSU95

possible (the phonons do not couple), so the thermal conductivity is in¢nite. In solids with (real) anharmonic interparticle interactions, there are two kinds of threephonon processes, which can be generally described in terms of their energy (represented by the frequency, !Þ and momenta (represented by the wave vector, kÞ: (1) An A event involves annihilation of two phonons and creation of a third phonon: ð4Þ !ðk1 Þþ!ð k2 Þ ¼ !ð k3 Þ; k1 þ k2 ¼ k3 þG:

ð5Þ

(2) A B event represents annihilation of one phonon with creation of two phonons: ð6Þ !ðk1 Þ ¼!ð k2 Þþ!ð k3 Þ; k1 þG ¼ k2 þ k3 :

ð7Þ

G is a reciprocal lattice vector. Depending on the extent of involvement of the crystal as a whole in the scattering, there are so-called normal processes (N-process, G = 0) and Umklapp processes (U-process, G 6¼ 0). N-processes do not interfere with the phonon stream, but in£uence heat transfer indirectly through a change of the phonon frequency distribution.13 U-processes provide the dominant thermal resistance mechanism in insulating solids. In this process the sum of wave vectors of colliding phonons falls outside of the ¢rst Brillouin zone (see also Chapter 1.1), and thus the resultant phonon wave vector opposes the phonon stream, e¡ectively giving rise to thermal resistivity. Callaway14 assumed that di¡erent scattering mechanisms act independently and introduced a total phonon relaxation rate, 1/ tot , as the sum of scattering rates due to diverse elastic scattering mechanisms (1/ S Þ and phonon^phonon scattering (1/ N + 1/ U ), for N- and U-processes, respectively. Consideration of the Boltzmann equation for phonon distribution ; 15 @N @N ¼ ðv rT Þ ; ð8Þ @t @T where N is the phonon concentration and t is time, in the Debye regime of heat transfer [considering heat transfer via acoustic phonons given by Eq. (3)], yields the thermal conductivity coe⁄cient, , as a sum of two parts 1 and 2 : 15 D

9 ZT 8 x4 ex 2kB T >3 kB > ; : 1 ¼ dx tot 2 2 v h ðex 1 Þ2

ð9Þ

0

and

8R 93 : D =T 8 0 k :2kB T > ; R 2 ¼ B2 > D =T 2 v h 0

tot N

92 x4 ex ðex 1 Þ2 dx;

tot N U

x4 ex ðex 1 Þ2 dx

:

ð10Þ

When N-processes are dominant, the relative relaxation processes are U >> N , tot

96

Chap. 1.3

THERMAL CONDUCTIVITY OF INSULATORS AND GLASSES

N , so 2 is the main term. Alternatively, if resistive processes dominate, N >> U , tot U , and 1 contributes more to the overall thermal conductivity. Complete exclusion of the U-processes results in an in¢nite conductivity, as the denominator in Eq. (10) goes to zero. This is in agreement with the concept of zero thermal resistivity in ideal (harmonic) crystals. The N-processes are important only at very low temperatures and in nearly perfect, low-anharmonicity crystals. At present there are several expressions for the relaxation rate due to the Uprocesses, 1/U ,1619 but for dielectric solids, the most widely applied formula is as follows : 16 1 ¼ A !2 T eBD =T ; ð11Þ U where A and B are constants. At very low temperatures (T 10 K for a single crystal with linear dimensions 0.01 m), boundary scattering becomes important. The boundary scattering rate, 1/b , can be expressed as20 1 1:12v ¼ ; ð12Þ b d where d is the dimension of the single crystal. Doped crystals can have large contributions to the resistivity mechanism from impurity scattering. The rate of this scattering, 1/i , was shown to be proportional to the fourth power of phonon frequency: 21 1 ¼ A0 !4 ð13Þ i with a temperature-independent parameter, A0 , given by10 8 9 M >2 V0 > 0 : ;; A ¼ 4v3 M

ð14Þ

where V0 is the e¡ective volume of the defects, M is the mass of the regular elementary unit of the substance, and M is the di¡erence in mass between the defect and the regular unit. 2.2. Temperature Dependence of At quite high-temperatures (T >>D Þ, the thermal resistivity is dominated by umklapp processes, and the relaxation, given by Eq. (11), leads to a reduction in the mean free phonon path (Þ as the temperature increases. Correspondingly, T 1 for well-ordered solids at T > D .5 As the temperature decreases, grows longer until it approaches its limit, which is governed by imperfections or by boundary scattering. Since the velocity of sound varies little with temperature, the other major factor to consider for is the heat capacity [see Eq. (1)], which is approximately constant at T >>D , and gradually decreases as T ! 0 K. A schematic view of the thermal conductivity and the corresponding mean free phonon path in a simple, insulating solid is shown in Fig. 1.

Sec. 3

MORE COMPLEX INSULATORS: THE ROLE OF OPTIC MODES

97

λ

κ θ D/10

T FIGURE 1 Schematic view of the thermal conductivity, , and the phonon mean free path, , as functions of temperature for a simple, insulating solid. Note that the peak in occurs at a temperature about 10% of the Debye characteristic temperature, D .

2.3. Impurities Impurities predominantly lower the phonon mean free path by adding additional scattering centers, while having little e¡ect on the heat capacity or velocity of sound of a solid. Therefore, the impurities have the largest e¡ect on at low temperatures where the phonon mean free path would otherwise be limited by boundaries (for a pure single insulating crystal). The e¡ect of impurities has been most e¡ectively studied in the case of the thermal conductivity of diamond. Owing to the strong carbon^carbon interaction in diamond, the Debye temperature of diamond is very high, about 2200 K,22 leading to an exceptionally high velocity of sound (ca. 1800 m s1 Þ. Hence, the thermal conductivity of diamond is extraordinarily large, ca. 2000 W m1 K1 at room temperature.23 However, isotopically puri¢ed diamond (99% 12 C) has an even higher thermal conductivity, about 4000 W m1 K1 at room temperature, and increasing to 41,000 W m1 K1 at T = 100 K.24 The increase in thermal conductivity on removal of isotopic impurities has been explained in terms of the Nprocesses.25 Although the thermal conductivity usually is lowered with impurities, because the impurities gives rise to phonon scattering, the thermal conductivity of a semiconductor can be increased on addition of n- or p-type impurities, because they provide increased electronic heat conduction which can more than compensate for the reduction in phononic heat conduction. 3. MORE COMPLEX INSULATORS: THE ROLE OF OPTIC MODES 3.1. Molecular and Other Complex Systems Although the acoustic phonons are the predominant carriers of thermal energy in simple insulators, and acoustic modes are usually considered to be well separated from optic modes, this is not always the case, especially in materials with large numbers of atoms per unit cell. As mentioned, for n atoms per unit cell, 3 modes

98

Chap. 1.3

THERMAL CONDUCTIVITY OF INSULATORS AND GLASSES

would be acoustic, and the remaining (3n ^ 3) degrees of freedom would be associated with optical modes. If n is large, and some of the optic modes are close to the frequency range of the acoustic modes, in principle, this could give rise to interactions between the acoustic modes and the optic modes, making understanding of the thermal conductivity much more di⁄cult in most cases. Furthermore, since many of the optic modes are at very high frequencies, the Dulong^Petit-type considerations of the heat capacity are not appropriate for molecular systems (although they are often used5 ), so Eq. (1) cannot be applied without experimental information concerning heat capacities. The number of optical modes is especially important for molecular solids because of the potential for large numbers of atoms per unit cell. Furthermore, molecules can have additional degrees of freedom which can interfere with heat conduction. For example, whereas the thermal conductivities of solid Ar, Kr and Xe can be expressed as a universal function of reduced thermal resistivity, 1 /((r0 /kB ) (M/)1=2 , where r0 is the nearest-neighbor distance, M is the molecular mass and is the static binding energy, as a function of reduced temperature, T /(/kB ), for T > 0.25D ,26 the thermal conductivity of solid N2 , in both the -phase and the -phase, is less than that of the solidi¢ed inert gases because of additional phonon scattering mechanisms associated with phonon^libron interactions. Furthermore, the thermal conductivity of N2 in the orientationally disordered -phase is about 20% less than in the ordered -phase.26; 27 This is attributed to the interaction of heat-carrying phonons with £uctuations associated with orientational disorder of the N 2 molecules.26 Similarly, measurements of of CH4 from 22 to 80 K (in the hightemperature orientationally disordered solid phase) show28 to be small (0.4 W m1 K1 Þ and with only a slight maximum at about 50 K. Another interesting case is C60 . In its high-temperature orientationally disordered phase, is small (0.4 W m1 K1 Þ and essentially independent of temperature.29 This has been attributed to e⁄cient phonon scattering due to orientation disorder, with a calculated mean free path of only a few lattice spacings. On cooling below the ordering transition at 260 K, of C60 increases abruptly by about 25%.29 Within the low-temperature simple cubic phase of C60 , the approximate temperature dependence is T 1 , as one would expect from phonon^phonon Umklapp scattering processes, but a more accurate ¢t to the temperature dependence is achieved by inclusion of scattering from misoriented molecules29 or from point defects.30 The crystalline phases of ice present many fascinating ¢ndings with regard to thermal conductivity. For the normal phase of ice, Ih, T 1 for T > 40 K, consistent with acoustic phonons carrying the heat and being primarily limited by three-phonon Umklapp processes.31 At ‘high’ temperatures, of ice Ih is close to a value calculated based on phononic thermal conductivity in a simple lattice with vibrating point masses of average molecular mass 18, with O^H rotations and vibrations making relatively little contribution.31 Furthermore, for ice Ih is abnormally high at the melting point compared with liquid water; the phonon mean free path for ice Ih at 273 K is about 30 lattice constants, which shows that is greater than its minimum value.31 When a small amount of NaOH is added to ice, this orders the protons and produces ice XI; increases 15% increase at the Ih!XI transformation, consistent with Umklapp processes and point defects as the main thermal resistance mechanisms in Ih and XI, with the XI phase closer to a harmonic lattice due to proton ordering.32 In general, within the various ice phases, , expressed as Tn , falls into two groups, either with n 1 or n0.7.

Sec. 3

MORE COMPLEX INSULATORS: THE ROLE OF OPTIC MODES

99

The phases for which n 1 are either proton disordered (phase Ih) or essentially completely antiferroelectrically ordered (phases II, VIII, and IX). The phases with n < 1 (III, V, VI, VI’, and VII) are paraelectric.33 Thermal conductivity of n-alkanes near room temperature is of considerable interest because of the use of these materials as latent^energy storage materials. At 0‡C, the thermal conductivity of n-Cm H2mþ2 (m = 14 to 20) was found to show two distinct trends (one for m = even, one for m = odd ; the reason for the di¡erentiation is that packing is di¡erent for the two types of zigzag chains) with increasing linearly with m in both cases.34 The thermal conductivity of the oddcarbon members was about 30% lower than for even carbon numbers. (It should be noted that the apparent thermal conductivity of n-C20 H42 was found to depend on the conditions under which the sample was solidi¢ed.35 ) In contrast with globularshaped molecules where increases by only about 5% on solidi¢cation, for Cm H2mþ2 (m = 9,11,13,..,19) increases by about 35% on solidi¢cation.36;37 Further substantial increase in was observed on cooling from the high-temperature disordered solid phase to the low-temperature solid phase, with the thermal conductivity increasing with carbon chain length.36;37 The latter ¢nding was attributed to strong intrachain bonds giving rise to more e⁄cient heat conduction.37 In the lowtemperature phase under isobaric conditions, was found to depend more strongly on temperature than T 1 , due to thermal expansion e¡ects.37 Although there is no strict theoretical basis, as there is for simpler, insulating solids, we can conclude that molecular solids in which there is dynamic disorder showed lowered , commensurate with shorter mean free paths because of additional coupling mechanics (including possibly coupling of the acoustic modes with low-lying optical modes) and a temperature dependence for T > D of the form T n , where n > 1. 3.2. Optic^Acoustic Coupling Although much of the heat £ux is carried by acoustic modes, and optic modes are usually considered to be far higher in energy than acoustic modes, in some systems, the optic modes can be close enough in energy to the acoustic modes to allow optic^acoustic coupling. We now examine a few such cases. In inclusion compounds that is, systems in which there is a host lattice in which other atoms or molecules reside as loosely associated guests it is possible to have resonant scattering due to the coupling of the lattice acoustic modes with the localized low-frequency optical modes of the guest species. In some cases this can be the dominant phonon scattering mechanism;38;39 and it can be represented by a phenomenological expression for the resonant scattering rate, 1/R : 40;41 !0 2 !2 1 ¼ N0 D ; R ð!0 2 !2 Þ2

ð15Þ

where N0 is the concentration of guest, D is a coe⁄cient depicting the strength of host^guest coupling, and !0 is the characteristic resonant frequency. If this mechanism su⁄ciently contributes to the overall thermal resistance, this can lead to low values of and positive values of d/dT at temperatures above about 10 K, similar to the behavior of for a glass (vide infra). A similar mechanism has been used to describe the interaction of side-chain motions in a polymer with acoustic phonons.42 Furthermore, other molecular sys-

100

Chap. 1.3

THERMAL CONDUCTIVITY OF INSULATORS AND GLASSES

tems exhibit similar contributions to thermal resistance.43 45 This mechanism has been suggested46 and proven47 to reduce thermal conductivity for applications in thermoelectrics. In general, this mechanism could be important in any systems with low-lying optical energy levels, e.g., due to dynamic disorder of ions or molecular units. 4. THERMAL CONDUCTIVITY OF GLASSES 4.1. Comparison with Crystals To a ¢rst approximation, the major distinctions between thermal conductivities of glasses and crystalline solids are that glasses have lower thermal conductivities and d/dT is positive for glasses and negative for simple crystalline solids.48 [This is somewhat of an oversimpli¢cation, as we also know (see Sec. 3.2) that crystalline materials can have low thermal conductivities with positive temperature coe⁄cients of , when optic^acoustic resonance scattering is important.] For example, the thermal conductivity of crystalline SiO2 is about 10 W m 1 K 1 at room temperature, whereas that of amorphous SiO2 is about 1 W m 1 K 1 .48 Furthermore, the thermal conductivities of glasses of a wide range of composition are similar both in magnitude and in temperature dependence.6 The higher thermal conductivity of crystalline cellulose, compared with amorphous cellulose, is the secret to successful popping corn.49 Based on the Debye model of the thermal conductivity of a solid [eq. (1)], Kittel50 explained the behavior of glasses in terms of an approximately constant mean free path for the lattice phonons, so the thermal conductivity closely follows the heat capacity. He found that the value of the phonon mean free path in a glass at room temperature is on the order of magnitude of the scale of disorder in the structure of the glass, viz. about 7 A. 4.2. More Detailed Models Many glasses have been shown to follow an almost universal temperature dependence of , including a very-low-temperature (T < 1 K) region with a steep positive slope, followed by a plateau between about 1 K and 20 K, and then a region of positive d/dT above about 20 K.6 The thermal conductivity of glasses below the plateau varies as T n , where n 2; it has been attributed to the scattering of phonons from low-lying energy states,6 which can be interpreted in a two-level system model.51;52 A Boson peak at a few meV in the Raman spectrum has been associated with these levels. In the region of the plateau, there are many di¡erent interpretations of the origins of the £at thermal conductivity, ranging from scattering from structural disorder,53 to tunneling interactions,54 to resonance scattering from localized vibrational modes55 and a soft-potential model in which the tunneling states and the localized resonant modes have a common origin.56 Kittel’s explanation of the thermal conductivity of a glass above the plateau showed that the phonon mean free path is of the order of the interatomic spacing, which is random in a glass, so the concept of phonons is not as apt a description as a random walk of localized (Einstein) oscillations.6 Cahill and Pohl considered a model of oscillators that are so strongly damped that they pass on their energy

Sec. 6

MINIMUM THERMAL CONDUCTIVITY

101

within half a period of oscillation; the thermal conductivity can be described as Eins ¼ 2 kB 2 l1 h1 E x2 ex ðex 1Þ2

ð16Þ

where l is the interatomic spacing, E is the Einstein temperature, and x ¼ E /T .6 Their more detailed approach considers a distribution of oscillators, representing the thermal conductivity in terms of an integration over frequencies, !: 6 R1 ¼ 13 dC ð17Þ d! vð!Þ lð!Þ d! : 0

Orbach and co-workers have devised a di¡erent model, in which the localized phonons are thermally activated to hop among inequivalent localized sites.57 The e¡ect of localized modes on thermal and other properties has been discussed by Buchenau.58 4.3. The Exception: Recent Amorphous Ice Results Although most amorphous phases are well described as above, recent studies of the low-density form of amorphous ice show its thermal conductivity to be more like that of a simple, crystalline solid, although the thermal conductivity of high-density amorphous ice is typical for a glass.59 It has been concluded that the thermal resistance in low-density amorphous ice is dominated by rather weak phonon^ phonon scattering, in sharp contract with results for other glasses.59 5. MINIMUM THERMAL CONDUCTIVITY As mentioned, a perfect harmonic crystal has no thermal resistance mechanism; hence, it has in¢nite thermal conductivity. Therefore it is worth considering the lower limit to the thermal conductivity. This point was addressed by Slack,3 from the perspective of insulators in which the phonons are maximally coupled, and as a function of the number of atoms in the unit cell. The experimental thermal conductivity of amorphous SiO2 above the plateau is close to the calculated minimum thermal conductivity, and for some crystalline systems the experimental thermal conductivity approaches the minimum as the temperature approaches the melting point.3 Further support for the concept of a minimal thermal conductivity comes from experimental studies of mixed crystals with controlled disorder.60 In the context of a random walk between Einstein oscillators of varying sizes, the minimum thermal conductivity can be expressed as6 8 92 cR=T 2 x3 ex min ¼ 2:48 kB n2=3 v :Tc ; dx ð18Þ ðex 1Þ2 0

where c is the cuto¡ frequency for that mode. The concept of minimal thermal conductivity can be a useful guide in attempts to develop materials with exceptionally low thermal conductivities (e.g., for thermoelectrics). The thermal conductivity of a dielectric can be reduced toward its theoretical minimum by increasing the size of the unit cell, the presence of heavy atoms, amorphization, random atomic substitution, increased optic^acoustic coupling and increasing the lattice symmetry.3

102

Chap. 1.3

THERMAL CONDUCTIVITY OF INSULATORS AND GLASSES

6. RADIATION We have concentrated our discussion on heat transfer by thermal conductivity through the sample, but wish to conclude with a reminder that in materials at very high-temperatures, especially above 700 K, radiative heat transfer must also be included. The measured thermal conductivity would be the sum of the intrinsic phononic thermal conductivity and the radiative contribution, where the latter is given by 16 2 3 radiation ¼ T ð19Þ 3 kr where is the refractive index, is the Stefan^Boltzmann constant, and kr is the Rosseland mean absorption coe⁄cient.61 The form of the radiative term shows that it becomes increasingly important as the temperature is increased. 7. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23.

R. L. Sproull The Conduction of Heat in Solids Sci. Am. December 92^102 (1962). Y. S. Touloukian, R. W. Powell, C. Y. Ho and P. G. Klemens, eds. Thermophysical Properties of Matter Vol. 2, Thermal Conductivity, Nonmetallic Solids (Plenum, New York, 1970). G. A. Slack The Thermal Conductivity of Nonmetallic Crystals Solid State Phys. 34, 1^71 (1979). R. G. Ross, P. Andersson, B. Sundqvist and G. Ba«ckstro«m Thermal Conductivity of Solids and Liquids Under Pressure Rep. Progr. Phys. 47, 1347^1402 (1984). R. G. Ross Thermal Conductivity and Disorder in Nonmetallic Materials Phys. Chem. Liq. 23, 189^ 210 (1991). D. G. Cahill and R. O. Pohl Lattice Vibrations and Heat Transport in Crystals and Glasses Ann. Rev. Phys. Chem. 39, 93^121 (1988). R. G. Ross Thermal Conductivity of Solids under Pressure High Temp.^High Press. 21, 261^266 (1989). C. Kittel Introduction to Solid State Physics, 7th ed. (Wiley, New York, 1996). M. A. White Properties of Materials (Oxford University Press, New York, 1999). P. G. Klemens Thermal Conductivity and Lattice Vibrational Modes, in Solid State Physics, Vol. 7, edited by F. Seitz and D. Turnbull, (Academic Press, 1958), pp. 1^98. P. Bru«esch Phonons: Theory and Experiments I (Springer-Verlag, Berlin, 1982). D. G. Cahill and R. O. Pohl Lattice Vibrations and Heat Transport in Crystals and Glasses Ann. Rev. Phys. Chem. 39, 93^121 (1988). J. Callaway Quantum Theory of the Solid State, 2nd ed. (Academic Press, San Diego, 1991). J. Callaway Model for Lattice Thermal Conductivity at Low Temperatures Phys. Rev. 113, 1046^ 1051 (1959). R. Berman Thermal Conductivity in Solids (Clarendon Press, Oxford, 1976). P. G. Klemens in Thermal Encyclopedia of Physics, Vol. 14, edited by S. Flugge (Springer-Verlag, Berlin, 1956), p. 198. R. Berman and J. C. F. Brock The E¡ect of Isotopes on Lattice Heat Conduction. I. Lithium Fluoride. Proc. R A 298, 46^65 (1965). J. Callaway and H. C. von Baeyer E¡ect of Point Imperfections on Lattice Thermal Conductivity Phys. Rev. 120, 1149^1154 (1960). J. E. Parrot and A. D. Stuckes Thermal Conductivity of Solids (Pion, London, 1975). H. B. G. Casimir Note on the Conduction of Heat in Crystals Physica 5, 495^500 (1938). P. G. Klemens Thermal conductivity of dielectric solids at low temperatures Proc. R. Soc., A 208, 108^133 (1951). J. E. Desnoyers and J. A. Morrison The Heat Capacity of Diamond between 12.8 and 277 K Phil. Mag. 8, 42^48 (1952). G. A. Slack Nonmetallic Crystals with High Thermal Conductivity J. Phys. Chem. Solids 34, 321^ 335 (1973).

Sec. 7

REFERENCES

103

24. L. Wei, P. K. Kuo, R. L. Thomas, T. R Anthony, and W. F. Banholzer Thermal Conductivity of Isotopically Modi¢ed Single Crystal Diamond Phys. Rev. Lett. 70, 3764^3767 (1993). 25. J. R. Olson, R. O. Pohl, J. W. Vandersande, A. Zoltan, T. R. Anthony, and W. F. Banholzer Thermal Conductivity of Diamond between 170 and 1200 K and the isotope e¡ect Phys. Rev. B 47, 14850^14856 (1993). 26. L. A. Koloskova, I. N. Krupskii, V. G. Manzhelii, and B. Ya. Gorodilov Thermal Conductivity of Solid Carbon Monoxide and Nitrogen Fizika Tverdogo Tela (Sankt-Peterburg) 15, 1913^1915 (1973). 27. P. Stachowiak, V. V. Sumarokov, J. Mucha, and A. Jezowski Thermal Conductivity of Solid Nitrogen Phys. Rev. B 50, 543^546 (1994). 28. V. G. Manzhelii and I .N. Krupskii Heat Conductivity of Solid Methane, Fizika Tverdogo Tela (Sankt-Peterburg) 10, 284^286 (1968). 29. R. C. Yu, N. Tea, M. B. Salamon, D. Lorents, and R. Malhotra Thermal Conductivity of SingleCrystal C60 Fullerene Phys. Rev. Lett. 68, 2050^2053 (1992). 30. B. Sundqvist Point Defects and Thermal Conductivity of C60 Phys Rev. B 48, 14712^14713 (1993). 31. G. A. Slack Thermal Conductivity of Ice Phys. Rev. B 22, 3065^3071 (1980). 32. O. Andersson and H. Suga Thermal Conductivity of the Ih and XI Phases of Ice Phys. Rev. B 50, 6583^6588 (1994). 33. R. G. Ross, P. Andersson, and G. Ba«ckstro«m E¡ects of H and D Order on the Thermal Conductivity of Ice Phases J. Chem. Phys. 68, 3967^3972 (1978). 34. D. W. Yarborough and C. N. Kuan The Thermal Conductivity of Solid n-Eicosane, n-Octadecane, n-Heptadecane, n-Pentadecane, and n-Tetradecane Thermal Conductivity 17, 265^274 (1981). 35. P. C. Stryker and E. M. Sparrow Application of a Spherical Thermal Conductivity Cell to Solid nEicosane Para⁄n Int. J. Heat Mass Transfer 33, 1781^1793 (1990). 36. H. Forsman and P. Andersson E¡ects of Temperature and Pressure on the Thermal Conductivity of Solid n-Undecane Ber. Bunsenges. Phys. Chem. 87, 490^495 (1983). 37. H. Forsman and P. Andersson Thermal Conductivity at High Pressure of Solid Odd-Numbered nAlkanes Ranging from Nonane to Nonadecane J. Chem. Phys. 80, 2804^2807 (1984). 38. J. S. Tse and M. A. White Origin of Glassy Crystalline Behaviour in the Thermal Properties of Clathrate Hydrates: A Thermal Conductivity Study of Tetrahydrofuran Hydrate J. Phys. Chem, 92, 5006^5011 (1988). 39. J. S. Tse, V. P. Shpakov, V. R. Belosludov, F. Trouw, Y. P. Handa, and W. Press Coupling of Localized Guest Vibrations with the Lattice Modes in Clathrate Hydrates Europhys. Lett. 54, 354^360 (2001). 40. C. T. Walker and R. O. Pohl Phonon Scattering by Point Defects Phys. Rev. 131, 1433^1442 (1963) 41. V. Narayanamurti and R. O. Pohl Tunneling States of Defects in Solids Rev. Mod. Phys. 42, 201^ 236 (1970). 42. M. N. Wybourne, B. J. Kiff and D. N. Batchelder Anomalous Thermal Conduction in Polydiacetylene Single Crystals Phys. Rev. Lett. 53, 580^583 (1984). 43. M. Zakrzewski and M. A. White Thermal Conductivities of a Clathrate with and without Guest Molecules Phys. Rev. B 45, 2809^2817 (1992). 44. D. Michalski and M.A. White Thermal Conductivity of a Clathrate with Restrained Guests: The CCl4 Clathrate of Dianin’s Compound J. Phys. Chem. 99, 3774^3780 (1995). 45. D. Michalski and M. A. White Thermal Conductivity of an Organic Clathrate: Possible Generality of Glass-like Thermal Conductivity in Crystalline Molecular Solids J. Chem. Phys. 106, 6202^6203 (1997). 46. G. A. Slack New Materials and Performance Limits for Thermoelectric Cooling, in CRC Handbook of Thermoelectrics (1995), pp. 407^440. 47. B. C. Sales, D. Mandrus and R. K. Williams. Filled Skutterudite Antimonides: A New Class of Thermoelectric Materials. Science 272, 1325^1328 (1996). 48. A. Eucken The Change in Heat Conductivity of Solid Metalloids with Temperature Ann. Phys. 34, 185^222 (1911). 49. W. J. da Silva, B. C. Vidal, M. E. Q. Martins, H. Vargas, A. C. Pereira, M. Zerbetto and L. C. M. Miranda What Makes Popcorn Pop Nature 362, 417 (1993). 50. C. Kittel Interpretation of Thermal Conductivity of Glasses Phys. Rev. 75, 972^974 (1949) 51. P. W. Anderson, B. I. Halperin, and C. M. Varma Anomalous Low-Temperature Thermal Properties of Glasses and Spin Glasses Philos. Mag. 25, 1^9 (1972). 52. W. A. Phillips Tunneling States in Amorphous Solids J. Low Temp. Phys. 7, 351^360 (1972).

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THERMAL CONDUCTIVITY OF INSULATORS AND GLASSES

53. R. Orbach Dynamics of Fractal Networks Science 231, 814^819 (1986). 54. M. W. Klein Dielectric Susceptibility and Thermal Conductivity of Tunneling Electric Dipoles in Alkali Halides Phys. Rev. B 40, 1918^1925 (1989) 55. E. R. Grannan, M. Randeria and J.P. Sethna Low-temperature Properties of a Model Glass. I. Elastic Dipole Model Phys. Rev. B 41, 7784^7798 (1990) 56. M. A. Ramos and U. Buchenau Low-temperature Thermal Conductivity of Glasses within the SoftPotential Model Phys. Rev. B 55, 5749^5754 (1997) 57. S. Alexander, C. Laermans, R. Orbach and H. M. Rosenberg Fracton Interpretation of Vibrational Properties of Cross-linked Polymers, Glasses, and Irradiated Quartz Phys Rev. B 28, 4615^4619 (1983) 58. U. Buchenau Dynamics of Glasses J. Phys. Condens. Matter. 13 7827-7846 (2001) 59. O. Andersson and H Suga Thermal Conductivity of Amorphous Ices Phys. Rev. B 65, 140201 (4 pages) (2002) 60. D. G. Cahill, S. K. Watson and R. O. Pohl Lower Limit to the Thermal Conductivity of Disordered Crystals Phys. Rev. B 46, 6131^6139 (1992) 61. U. Fotheringham Thermal Properties of Glass Properties of Optical Glass, 203^230 (SpringerVerlag, 1995)

Chapter 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS G. S. Nolas Department of Physics, University of South Florida, Tampa, FL, USA

H. J. Goldsmid School of Physics, University of New South Wales, Sydney, NSW, Australia

1. INTRODUCTION The conduction of heat in semiconductors has been the subject of intensive study during the past 50 years. From the practical point of view, thermal conductivity is an important parameter in determining the maximum power under which a semiconductor device may be operated. Moreover, thermal conductivity is one of the most important parameters determining the e⁄ciency of those semiconductors used in thermoelectric energy conversion.1 However, a number of factors have also made the study of semiconductors particularly important in advancing our knowledge of the mechanisms of heat conduction in solids. For example, the need for single crystals of exceptional perfection and purity has made available samples for measurement that display e¡ects that cannot be observed in less perfect specimens. Certain semiconductors have rather high electrical restivities, so heat conduction is then, in e¡ect, due solely to lattice vibrations. On the other hand, in some materials the electronic component of thermal conductivity is large enough to be important, and, indeed, this is always the case for semiconductors in thermoelectric applications. The separation of the lattice and electronic contributions to the thermal conductivity is often necessary. It becomes particularly interesting when the semiconductor contains both electrons and positive holes since there can then be a large bipolar heat conduction e¡ect. In a semiconductor with only one type of charge carrier, the ratio of the electronic thermal conductivity to the electrical

106

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

conductivity has more or less the same value that it would have in a metal. In other words, the ratio satis¢es the Wiedemann^Franz law or, rather, the version of this law that is appropriate for a nondegenerate or partly degenerate conductor. However, when bipolar conduction takes place, the ratio of electronic to lattice conductivity can become much larger. It is often useful to be able to preselect those semiconductors in which the value of the lattice conductivity will be very high or very low. It is also helpful if one can predict the types of treatment of a given material that will lead to a substantial reduction of the thermal conductivity. Thus, in this chapter, we shall give due attention to both these matters. Certain crystal structures allow one to modify the thermal conductivity in subtle ways. We are often especially interested in processes that reduce lattice conductivity but have relatively little e¡ect on electronic properties. These processes include, for example, the formation of solid solutions, addition of impurities, and reduction of grain size. The range of thermal conductivity in semiconductors is exceedingly large. A semiconducting diamond, for example, has a thermal conductivity higher than that of any metal, while some clathrates have values comparable with those of glasses. Table 1 gives values for the thermal conductivity at room temperature for various semiconductors. In many cases the total thermal conductivity will be virtually the same as the lattice contribution, but in others the electronic component will be substantial and will vary according to the concentration of charge carriers. The lattice conductivity, itself, may be signi¢cantly smaller for less than perfect crystals. 2. ELECTRONIC THERMAL CONDUCTIVITY IN SEMICONDUCTORS 2.1. Transport Coef¢cients for a Single Band One success of the classical theory of metals was its explanation of the Wiedemann^ Franz law. This law states that the ratio of thermal conductivity to electrical conductivity is the same for all metals at a given temperature. The actual value of the ratio was given only approximately, but this shortcoming was made good when Sommerfeld’s quantum theory of metals was applied.2 Other properties of metals required the additional re¢nement of band theory, and this, of course, is an essential feature of any discussion of semiconductors. We shall ¢rst discuss thermal conductivity when the charge carriers reside in a single band. It will be useful to obtain expressions for the electrical conductivity and the Seebeck coe⁄cient as well as for the electronic thermal conductivity. The electrical conductivity is needed to calculate the so-called Lorenz number, and the Seebeck coe⁄cient is required when we consider bipolar thermal conduction. We write equations for electric current and heat £ux when an electric ¢eld and a temperature gradient are applied. For our purposes we assume that the material is isotropic and that all £ows are in the x^direction. We suppose that the charge carriers are scattered in such a way that their relaxation time, , may be expressed in terms of the energy, E, by the relation = 0 E r , where 0 and r are constants. Then by solving the Boltzmann equation one ¢nds that the electric current, i; is given by Z 1 euf ðE ÞgðE ÞdE; ð1Þ i¼ 0

Sec. 2

ELECTRONIC THERMAL CONDUCTIVITY IN SEMICONDUCTORS

107

where ^e is the electronic charge, u is the velocity of the charge carriers in the x^ direction, f(EÞ is the Fermi distribution function, and g(EÞ is the carrier distribution function, g being proportional to E 1=2 . Here and in subsequent equations the upper sign refers to electrons and the lower sign to holes. The rate of £ow of heat per unit cross-sectional area is w ¼ uðE Þf ðE ÞgðE ÞdE;

ð2Þ

where is the Fermi energy and E ^ represents the total energy transported by a carrier. Since there can be no transport when f = f0 , we may replace f by f ^ f0 in the preceding equations. Also, in general, the thermal velocity of the charge carriers will always be much greater than any drift velocity, and we may set 2E u2 ¼ ; ð3Þ 3m where m* is the e¡ective mass of the carriers. From Eqs. (1^3) we ¢nd Z 1 9 8 2e @f 0 ðE Þ> @ E @T > ;dE; : i¼ g ð E Þ E þ e 3m 0 @E @x T @x and 2 w¼ iþ e 3m

Z

1 0

gðE Þe E 2

9 8 @f 0 ðE Þ> @ E @T > ;dE: : þ @E @x T @x

ð4Þ

ð5Þ

The electrical conductivity, , may be found by setting the temperature gradient, @T =@x; equal to zero. The electric ¢eld, E, is given by ð@=@xÞe1 so that Z 1 i 2e @f ðE Þ ¼ ¼ gðE Þe E 0 dE: ð6Þ E 3m 0 @E On the other hand, when the electric current is zero, Eq. (4) shows that Z Z @ 1 @f ðE Þ 1 @T 1 @f ðE Þ gðE Þe E 0 dE þ gðE Þe E ðE Þ e dE ¼ 0: @x 0 @E T @x 0 @E

ð7Þ

The condition i = 0 is that for the de¢nition of the Seebeck coe⁄cient and the thermal conductivity. The Seebeck coe⁄cient, , is equal to ð@=@xÞ½eð@T =@xÞ1 and is given by Z 1 Z 1 1 @f 0 ðE Þ 2 @f 0 ðE Þ ¼ gðE Þe E dE gðE Þe E dE : ð8Þ eT @E @E 0 0 The Seebeck coe⁄cient is negative if the carriers are electrons and positive if they are holes. The electronic thermal conductivity, e , is equal to wð@T =@xÞ1 and is obtained from Eqs. (5) and (7), thus *(Z 2 , 1 2 2 @f 0 ðE Þ e ¼ gðE Þe E dE 3m T @E 0 Z 0

1

@f ðE Þ gðE Þe E 0 dE @E

)

Z

1

0

+ @f 0 ðE Þ gðE Þe E dE : @E 3

ð9Þ

108

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

The integrals in Eqs. (6), (8), and (9) may be expressed as Z 1 8 2 3=2 1=2 @f ðE Þ Ks ¼ ð m Þ T E sþrþ3=2 0 dE; 0 2 3 h @E 0

ð10Þ

where g and e have been eliminated in favor of m*, r, and 0 . One then ¢nds that Z 1 9Z 8 3> 1 sþrþ1=2 sþrþ3=2 @f 0 ðE Þ > : E dE ¼ s þ r þ ; E f 0 ðE ÞdE ð11Þ @E 2 0 0 and

9 8 8 2 3=2 1=2 3 > ;ðkB T Þsþrþ3=2 F sþrþ1=2 ; :s þ r þ > Ks ¼ ð m Þ T 0 3 h2 2

where

Z F n ð Þ ¼

1

n f 0 ðÞd;

ð12Þ

ð13Þ

0

= E/kB T . Numerical values of the functions Fn , which are known as the Fermi^ Dirac integrals, may be found elsewhere. The expressions for the transport coe⁄cients in terms of the integrals Ks are ¼

ð14Þ

9 8 1 > K ;; : 1 > eT K0

ð15Þ

8 9 1 > K12 > > > e ¼ 2 :K2 ;: T K0

ð16Þ

¼ and

e2 K0 ; T

TABLE 1 Thermal Conductivity of Typical Samples of Some Elemental and Binary Compound Semiconductors at 300 K.a

Semiconductor

Thermal conductivity (W m1 K1 )

Diamond Silicon Germanium ZnS CdTe BN AlSb GaAs InAs InSb SnTe PbS 2.3 PbTe Bi2 Te3

200 124 64 14 5.5 20 60 37 29 16 9.1 2.3 2.3 2.0

a.

From CRC Handbook of Chemistry and Physics.

Sec. 2

ELECTRONIC THERMAL CONDUCTIVITY IN SEMICONDUCTORS

109

It may be necessary to use numerical methods to ¢nd the transport properties from Eqs. (15) and (16). However, if the Fermi energy is either much greater than or much less than zero, one can use simple approximations to the Fermi distribution function. 2.2. Nondegenerate and Degenerate Approximations The nondegenerate approximation is applicable when /kB T << 0; that is, when the Fermi level lies within the forbidden gap and far from the edge of the band in which the carriers reside. The approximation is very good when << ^4kB T , and is often used when << -2kB T . It is assumed that the number of minority carriers is negligibly small. When /kB T << 0, the Fermi^Dirac integrals are given by Z 1 n expðÞd ¼ expðÞðn þ 1Þ; ð17Þ F n ðÞ ¼ expðÞ 0

where g ¼ gv < =i >kB T and the gamma function is such that ðn þ 1Þ ¼ nðnÞ:

ð18Þ

When n is integral, ðn + 1) =n!, while for half-integral values of n the gamma function can be found from the relation (1/2) =1=2 . With the gamma function, the transport integrals become 8 9 8 9 8 > 2 >3=2 1=2 5 : 2 ; ðm Þ T 0 ðkB T Þsþrþ3=2 > :s þ r þ > ; expðÞ: Ks ¼ ð19Þ 3 h 2 Then the electrical conductivity of a nondegenerate semiconductor is 8 9 8 9 8 > 2 >3=2 2 1=2 5 : 2 ; e ðm Þ 0 ðkB T Þrþ3=2 > :r þ > ; expðÞ: ¼ 3 h 2

ð20Þ

It is often useful to express the electrical conductivity as ¼ ne; where n is the concentration of the charge carriers, Z 1 9 8 2m kB T >3=2 ; expðÞ; : f ðE ÞgðE ÞdE ¼ 2> n¼ h2 0 and their mobility is ¼

9 8 4 5 e0 ðkB T Þr > ; :r þ > : 2 m 31=2

ð21Þ

ð22Þ

ð23Þ

The carrier concentration has the value that would result if there were 2(2m*kB T / hÞ3=2 states located at the band edge. Thus, this quantity is known as the e¡ective density of states. The Seebeck coe⁄cient of a nondegenerate semiconductor is kB 5 ¼ rþ : ð24Þ e 2

110

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

It is usual to express the electronic thermal conductivity in terms of the Lorenz number, L, de¢ned as e /T. Then, from Eqs. (14) and (16), 9 8 1 > K2 K 21 > > L ¼ 2 2 : 2> ð25Þ ;: eT K0 K0 Using the nondegenerate approximation, we obtain 8 92 8 9 k 5 : B> ; > :r þ > ;: L¼> e 2

ð26Þ

The Lorenz number does not depend on the Fermi energy if r is constant. We now discuss the degenerate condition /kB T >> 0. This means that the Fermi level lies well inside the band that holds the charge carriers and the conductor is a metal. The Fermi^Dirac integrals take the form of the rapidly converging series F n ð Þ ¼

nþ1 2 74 þ nn1 þ nðn 1Þðn 2Þn3 þ ::: nþ1 6 360

ð27Þ

One uses as many terms in the series as are necessary to yield a ¢nite or nonzero value for the appropriate parameter. The electrical conductivity of a degenerate conductor needs only the ¢rst term in the series 8 9 8 > 2 >3=2 2 1=2 rþ3=2 : ; e ðm Þ 0 ¼ : ð28Þ 3 h2 On the other hand, if only the ¢rst term in Eq. (27) were included, the Seebeck coe⁄cient would be zero. To obtain a nonzero value, the ¢rst two terms are used, whence 2 kB r þ 32 ¼ : ð29Þ 3 e The ¢rst two terms are also needed for the Lorenz number, which is given by 8 9 2 >kB >2 L¼ : ; : ð30Þ 3 e This shows that the Lorenz number should be the same for all metals and, in particular, it should not depend on the scattering law for the charge carriers. These features agree with the well-established Wiedemann^Franz^Lorenz law, which states that all metals have the same ratio of thermal to electrical conductivity and that this ratio is proportional to the absolute temperature. Figure 1 shows the Lorenz number plotted against the reduced Fermi energy, , for di¡erent values of the scattering parameter, r. 2.3. Bipolar Conduction So far it has been assumed that the carriers in only one band contribute to the transport processes. Now we consider what happens when there is more than one type of carrier. The most important example is that of mixed and intrinsic semiconductors in which there are signi¢cant contributions from electrons in the con-

Sec. 2

ELECTRONIC THERMAL CONDUCTIVITY IN SEMICONDUCTORS

111

FIGURE 1 Dimensionless Lorenz number plotted against reduced Fermi energy for di¡erent values of the scattering parameter r.

duction band and holes in the valence band. The problem will be discussed for two types of carrier (represented by subscripts 1 and 2). There will be contributions to the electric current density, i, from both types of carriers. These contributions may be expressed in terms of partial electrical conductivities and partial Seebeck coe⁄cients. Thus, 9 8 9 8 @T @T > ;; i2 ¼ 2 > :E 1 > ;: :E 2 i1 ¼ 1 > ð31Þ @x @x where E is the electric ¢eld. The partial coe⁄cients may be found by using the expressions that have already been obtained for single bands. When the electric ¢eld and the temperature gradient are in the same direction, the thermoelectric emf opposes E for a positive Seebeck coe⁄cient and assists E when the Seebeck coe⁄cient is negative. If the temperature gradient is zero, i ¼ i1 þ i2 ¼ ð1 þ 2 ÞE; ð32Þ and the electrical conductivity is simply ¼ 1 þ 2 :

ð33Þ

If the electric current is equal to zero, as it is when i1 and i2 are equal and opposite, @T ð1 þ 2 ÞE ¼ ð1 1 þ 2 2 Þ ð34Þ @x and the Seebeck coe⁄cient is ¼

1 1 þ 2 2 : 1 þ 2

ð35Þ

If we now examine the thermal £ow, the heat £ux densities due to the two carrier types are

112

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

w1 ¼ 1 T i1 e;1

@T ; @x

w2 ¼ 2 T i2 e;2

@T ; @x

ð36Þ

where the contributions from the Peltier e¡ect have been expressed in terms of the partial Seebeck coe⁄cients by use of Kelvin’s relation. Since the thermal conductivity is de¢ned in the absence of an electric current, i1 and i2 must again be equal and opposite. We ¢nd that 1 2 @T i1 ¼ i2 ¼ ð1 2 Þ : ð37Þ 1 þ 2 @x By substitution into Eq. (36), the total heat £ux density is 1 2 @T 2 w ¼ w1 þ w2 ¼ e;1 þ e;2 þ ð2 1 Þ T ; 1 þ 2 @x

ð38Þ

and e ¼ e;1 þ e;2 þ

1 2 ð2 1 Þ2 T : 1 þ 2

ð39Þ

The remarkable feature of Eq. (39) is that the total electronic thermal conductivity is not just the sum of the partial conductivities, e;1 and e;2 . The presence of the third term arises from the Peltier heat £ows that can occur when there is more than one type of carrier, even when the total electric current is zero. The di¡erence, 2 ^ 1 , between the partial Seebeck coe⁄cients is, of course, greatest when the two carriers are holes and electrons, respectively. Thus, we expect e to be substantially greater than e;1 þ e;2 for an intrinsic semiconductor. The additional contribution, known as the bipolar thermodi¡usion e¡ect6 is observed most easily in semiconductors that have a small energy gap. Although 2 ^ 1 is then smaller than it would be for a wide-gap semiconductor, intrinsic conduction takes place with reasonably large values for the partial electrical conductivities, 1 and 2 . If 1 and 2 are too small, the electronic component of the thermal conductivity, even including bipolar thermodi¡usion, is masked by the lattice component. One of the ¢rst materials to display the bipolar e¡ect was the semiconductor bismuth telluride.7 Figure 2 shows the thermal conductivity plotted against temperature for lightly and heavily doped samples. It will be seen that, as the lightly doped sample becomes intrinsic at the higher temperatures, its thermal conductivity becomes much greater than that of the extrinsic heavily doped sample, even though it has a much smaller electrical conductivity. In fact, the Lorenz number is an order of magnitude greater for intrinsic bismuth telluride than it is for an extrinsic sample. 2.4. Separation of Electronic and Lattice Thermal Conductivities The total thermal conductivity of a semiconductor is usually simply the sum of the lattice contribution, L , and the electronic component, e . Thus, the knowledge of the electronic contribution allows the lattice component to be determined. Although the calculation of the electronic thermal conductivity using the relationships derived from Eq. (16) often gives reasonable results, it sometimes leads to unacceptable conclusions. For example, Sharp et al.8 found that certain polycrystalline samples of a Bi^Sb alloy would have negative lattice conductivity if theoretical

Sec. 2

ELECTRONIC THERMAL CONDUCTIVITY IN SEMICONDUCTORS

113

κ (Wm-1K-1) 3.5 3 2.5 near-intrinsic

2 1.5 150

extrinsic

200

250

300

T/K FIGURE 2 Plot of thermal conductivity against temperature for lightly and heavily doped samples of bismuth telluride.

values for the Lorenz number were assumed. It is, therefore, important to be able to determine the electronic thermal conductivity by an experimental method. One possibility is to measure the thermal conductivity for di¡erently doped samples of a given semiconductor. These samples will then have di¡erent values of the electrical conductivity and of the electronic thermal conductivity. One can then plot the thermal conductivity against the electrical conductivity; extrapolation of the plot to zero electrical conductivity should then give a value for the lattice component. As will be seen from Figure 3, in which the procedure has been carried out for bismuth telluride at 300 K, there can be some di⁄culties.9 The onset of intrinsic conduction at low values of the electrical conductivity causes the Lorenz number to become exceptionally large, as already mentioned. Also, there is the possibility that the doping agents used to alter the carrier concentration may themselves scatter the phonons and, thereby, change the lattice conductivity. Nevertheless, measurements on di¡erently doped samples o¡er one of the best methods of separating the two components of thermal conductivity. When the mobility of the charge carriers is su⁄ciently high, another method of determining the electronic thermal conductivity becomes possible. The thermal resistivity, like the electrical resistivity, is increased by the application of a transverse magnetic ¢eld. In most cases the lattice conductivity remains unchanged. In certain cases it is possible to apply a magnetic ¢eld that is large enough for the electronic thermal conductivity to become negligible in comparison with the lattice contribution. However, even when the mobility of the charge carriers is not large enough for this to occur in the available magnetic ¢eld, the magnetothermal resistance e¡ect is still useful. For example, the thermal conductivity can be plotted against the electrical conductivity as the magnetic ¢eld changes. Extrapolation to zero electrical conductivity allows the Lorenz number to be found. In one situation, however, the electronic thermal conductivity does not become zero, no matter how large the magnetic ¢eld strength is, namely when the Nernst^ Ettingshausen ¢gure of merit is large. The residual electronic thermal conductivity in this case is due to the transverse thermoelectromagnetic e¡ects.10 The e¡ect is

114

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

FIGURE 3 Plot of thermal conductivity against electrical conductivity for bismuth telluride at 300 K.

noticeable in Bi and Bi^Sb alloys, the latter being narrow-gap semiconductors for a range of Bi:Sb ratios. Uher and Goldsmid11 have shown how the electronic thermal conductivity can be determined in single crystals of Bi and its alloys by measuring the magnetothermal resistance for two orientations of the sample. It is rather di⁄cult to predict the magnitude of the Nernst^Ettingshausen ¢gure of merit and, thence, the size of that part of the thermal conductivity in a high magnetic ¢eld due to the transverse e¡ects. However, it is quite simple to calculate the ratio of the residual electronic thermal conductivities for two orientations. It is then a straightforward matter to separate out the lattice conductivity. 3. PHONON SCATTERING IN IMPURE AND IMPERFECT CRYSTALS 3.1. Pure Crystals Phonons can be scattered by impurities and by crystal defects. Thus, when good heat conduction from a semiconductor device is required, it is an advantage for the material to have a rather high thermal conductivity. It is, in fact, fortunate that pure silicon has such a thermal conductivity and that most semiconductor devices require rather pure and perfect material. However, for those semiconductors that are used in thermoelectric energy conversion, a low thermal conductivity is needed. It is, therefore, of interest to consider the means by which the lattice thermal conductivity can be made smaller. The lattice conductivity, L , can be expressed in terms of the mean free path, lt ,

Sec. 3

PHONON SCATTERING IN IMPURE AND IMPERFECT CRYSTALS

115

of the phonons by the equation 1 L ¼ cv vlt : 3

ð40Þ

Here cv is the speci¢c heat per unit volume due to the lattice vibrations, and v is the speed of sound. For many purposes it is a reasonable approximation to use Debye theory12 for the speci¢c heat and to assume that the speed of the phonons is independent of frequency. This is particularly true for imperfect crystals, since the higher-frequency phonons, for which Debye theory is most likely to break down, are then rather strongly scattered and do not make much of a contribution to heat conduction. If the thermal vibrations were perfectly harmonic, the free path length of the phonons would be in¢nite in a perfect unbounded crystal. However, as the temperature rises above absolute zero, the vibrations become more and more anharmonic. This causes the mean free path to vary inversely with temperature at hightemperatures. It was shown by Peierls13 that the phonon scattering events are of two kinds. The normal (or N-)processes conserve momentum and do not lead directly to any thermal resistance, though they do redistribute the momentum within the phonon system. Then there are the umklapp (or U-) processes, in which momentum is not conserved, and these events are responsible for the observed ¢nite thermal conductivity. At high-temperatures the speci¢c heat and the sound velocity may be regarded as constant. As the temperature is raised, the increasing probability of U-processes means that L varies as 1/T . This is consistent with the observations of Eucken14 and later workers. At very low temperatures U-processes become rather improbable, and it was predicted by Peierls that there should be an exponential increase in lattice conductivity when T << D , D being the Debye temperature. In fact, such an exponential variation is rarely observed because other factors invariably take over in real crystals. For example, the free path length of the phonons will certainly be limited by the crystal boundaries unless there is completely specular re£ection. Bearing in mind that the speci¢c heat itself tends to zero as T ! 0, the lattice conductivity also tends to zero. There is, then, some temperature at which the thermal conductivity has a maximum value. The inverse variation of L with temperature is often observed when T is as small as D or even less, despite the original prediction that this would only occur for T >> D . 3.2. Scattering of Phonons by Impurities Impurities scatter phonons because they produce local variations of the sound velocity through change in density or elastic constants. However, point-defect scattering presents us with a theoretical problem. The relaxation time for such scattering should vary as 1/!4 , where ! is the angular frequency of the phonons. We expect, then, that low^frequency phonons will be little a¡ected by point^defect scattering. We also know that U-processes are ine¡ective for low^frequency phonons, so we would expect exceedingly large values for lattice conductivity at low temperatures. Such values are not, in fact, observed. This dilemma can be resolved by taking into account the N-processes. Although the N-processes do not change the momentum in the phonon system, they do redistribute this quantity between di¡erent phonons. This redistribution can pass on the momentum to higher^fre-

116

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

quency phonons that are more strongly in£uenced by U-processes and impurity scattering. How, then, does one take into account the e¡ect of the N-processes ? The problem has been solved by Callaway,15 who suggested that the N-processes cause relaxation toward a phonon distribution that carries momentum, whereas the U-processes and impurity scattering cause relaxation toward a distribution that does not carry momentum. This means that the relaxation time, R , for the nonmomentum-conserving processes, has to be replaced by a relaxation time, eff , which is related to R and the relaxation time, N , for the N-processes by 98 8 9 9 8 1 1 1 > 1 1 > 1 ;:1 þ > : þ > ; ¼ :1 þ > ; ; ¼> ð41Þ eff R N N c N where c is the relaxation time that would have been expected if the N-processes did not conserve momentum, and is a constant that must be selected so that the Nprocesses are indeed momentum conserving. If it is assumed that the Debye model for the phonon distribution is valid, as it should be for the low-frequency modes with which we are most concerned, then ,Z Z D =T 8 9 D =T c 4 exp x 1 > c > 4 exp x : ;x ¼ x dx 1 dx; ð42Þ 2 N ðexp x 1Þ N N ðexp x 1Þ2 0 0 where x = h!/2kB T . In certain situations this complex expression may be simpli¢ed. For example, if the scattering by imperfections is very strong, with a relaxation time I << N , one can use the approximation 1/ eff 1/ I + 1/ N . Parrott16 has used a high-temperature approximation that should be valid for most thermoelectric materials. He supposed that the relaxation times for the U- and N-processes are proportional to !2 , while for point defects I is proportional to !4 . We use the following expressions for the relaxation times : 1/ I = A!4 , 1/ U = B!2 , 1/ N = C!2 , where A; B; and C are constants for a given sample. Also, at high-temperatures x << 1 for the whole phonon spectrum, so x2 exp x/(exp x ^ 1)2 1. This allows us to obtain the relatively simple equation 92 8 4 8 91 # 9" 8 L > 5k0 > tan1 y > tan1 y> y ð1 þ k0 Þ y2 tan1 y> > > > > > ; ¼ :1 þ þ :1 y ; ; : ; 0 9 y y 5k0 3 y ð43Þ where k0 ¼ C/B is the strength of the N-processes relative to the U-processes, and y is de¢ned by the equation 9 8 !D 2 > 5k0 >1 2 ; ; : y ¼ 1þ ð44Þ !0 9 with !0 given by

8 92 ! k > ; ¼ 2 B : 0> : !D 2 v0 !D A

ð45Þ

The value of k0 can be found experimentally by measuring the thermal conductivity of two crystals, one pure and one containing impurities. It is, of course, necessary that one know the value of the parameter which determines the relaxation time for the defect scattering. This parameter may be calculated most easily when the scat-

Sec. 3

PHONON SCATTERING IN IMPURE AND IMPERFECT CRYSTALS

117

tering by density £uctuations outweighs that due to variations in the elastic constants. The reduction of thermal conductivity due to mass^defect scattering was certainly observed for germanium crystals with di¡erent isotopic concentrations.17 Mass^defect scattering has also been dominant in certain semiconductor solid solutions, though in others it must be presumed that variations in the elastic constants have also been an important factor. When mass^defect scattering occurs, then 2 X xi Mi M A¼ 3 ; ð46Þ 2v N i M2 where xi is the concentration of unit cells of mass Mi , M is the average mass per unit cell, and N is the number of unit cells per unit volume. At high-temperatures it is quite a reasonable approximation to ignore the Nprocesses in many systems. If we assume that the U-processes dominate the Nprocesses, k0 ! 0, and Eq. (43) becomes 8 9 L ! 0 ! ;: : D> ¼ tan1 > ð47Þ 0 !D !0 Note that new materials exist for which these simple ideas about scattering are inapplicable. For example, there are semiconductors, such as those with clathrate structures,18 in which the crystals contain open cages in which foreign atoms can reside. These atoms are loosely bound and are known as rattlers. They are very e¡ective in scattering phonons, sometimes reducing the thermal conductivity to a value that is close to that in an amorphous substance.19;20 This type of material will be discussed elsewhere. 3.3. Boundary Scattering The scattering of phonons on the crystal boundaries has been known since the work of Casimir,21 but for many years it was thought to be essentially a low-temperature phenomenon. However, it is now thought that boundary scattering may occur at larger grain sizes and higher temperatures than was previously thought possible. It is indeed possible that boundary scattering may sometimes have a greater e¡ect on lattice conductivity than on carrier mobility, even when the mean free path is larger for electrons or holes than it is for phonons. An enhanced boundary scattering e¡ect was proposed by Goldsmid and Penn22 on the basis that, although the number of low^frequency phonon modes is small, they make a substantial contribution to the thermal conductivity because they have a large free path length. This is illustrated by Figure 4, in which the contribution to the lattice conductivity from phonons of angular frequency ! is plotted against !. The area under the curve up to the Debye frequency, !D , indicates the contribution from all the phonons. The upper curve represents schematically the behavior of a large pure crystal. The double-hatched region represents the reduction in thermal conductivity due to boundary scattering when the grain size is still substantially larger than the mean free path. The e¡ect of boundary scattering becomes relatively larger for a solid solution in which the high^frequency phonons are strongly scattered, thus removing the contribution shown by the single-hatched region. Since solid solutions are the most frequently employed material for thermoelectric applications, it is possible that boundary scattering of phonons may improve the ¢gure of merit.

118

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

If one uses the Debye model for the phonon distribution, one ¢nds that the lattice conductivity of a sample of a solid solution having an e¡ective grain size L is given by rﬃﬃﬃﬃﬃﬃ 2 lt L ¼ S 0 ; ð48Þ 3 3L where S is the lattice conductivity of a large crystal of the solid solution and lt is the phonon mean free path.23 The parameter 0 , the thermal conductivity in the absence of point^defect scattering, can be estimated from the values for the di¡erent components of the solid solution. 4. PREDICTION OF THE LATTICE THERMAL CONDUCTIVITY It would be useful if we could predict the types of semiconductors, that would be likely to have a very high or a very low thermal conductivity. We outline here the kind of approach that has been used for this purpose in the high^temperature region. Bearing in mind the approximate nature of the predictive methods, we assume the Debye model. One of the earliest approaches to the problem was that of Leibfried and Schlo«mann,24 who used the variational method to show that 8 93 k MV 1=3 3D : B> ; L ¼ 3:5> ; ð49Þ h 2 T where M is the average atomic mass, V is the average atomic volume, and is the Gru«neisen parameter. An alternative approach that leads to more or less the same result was based on the proposal by Dugdale and MacDonald25 that the lattice conductivity should be related to the thermal expansion coe⁄cient T . The anharmonicity of the thermal

FIGURE 4 Schematic plot of the contributions to thermal conductivity from di¡erent parts of the phonon spectrum. The double-hatched region represents reduced thermal conductivity due to boundary scattering, the single-hatched region that due to alloy scattering in a solid solution.

Sec. 4

PREDICTION OF THE LATTICE THERMAL CONDUCTIVITY

119

vibrations can be represented by the dimensionless quantity T T, and it was suggested that the phonon mean free path should be approximately equal to the lattice constant a divided by this quantity. Thus, cV av L ¼ : ð50Þ 3T T The expansion coe⁄cient is given by the Debye equation of state: cV T ¼ ; 3

ð51Þ

where is the compressibility. Also, the speed of sound and the compressibility are related to the Debye temperature through the equation 2kB aD v ¼ ðÞ1=2 ¼ ; ð52Þ h where is the density. When these ideas were ¢rst considered, they were applied to simple crystals having small numbers of atoms per unit cell. No distinction was drawn between the acoustic and optical modes and a was set equal to the cube root of the atomic volume. It was then found that 8 93 k MV 1=3 3D ; : B> L ¼ 8> : ð53Þ h 2 T This di¡ers from Eq. (49) only in the value of the numerical constant. Notice that Eq. (53) and (49) require a knowledge of the Debye temperature and, therefore, might not be as useful as they otherwise would be. Using the Lindemann melting rule to estimate the compressibility, Keyes26 obtained a formula that does not have this objection. Thus, "m V ¼ ; ð54Þ RTm where R is the gas constant and Tm is the melting temperature. This rule makes use of the assumption that a solid melts when the amplitude of the lattice vibrations reaches a fraction "m of the lattice constant, "m being approximately the same for all substances. Then, from Eq. (50) through (52) we ¢nd L T ¼ B

Tm3=2 2=3 ; Am

ð55Þ

where B¼

R3=2 1=3

3 2 "3m NA

;

ð56Þ

NA is Avogadro’s number, and Am is the mean atomic weight. The advantage of Keyes’ Eq. (55) is that it involves the quantities Tm , , and Am , which are known as soon as a new material is synthesized, and a quantity B that should not vary much from one substance to another in a given system. For 7=6 for semiexample, Figure 5 shows the values of L T plotted against Tm3=2 2=3 Am conductors with covalent or partly covalent bonds. As expected from Eq. (55), the plot is approximately linear.

120

Chap. 1.4

THERMAL CONDUCTIVITY OF SEMICONDUCTORS

FIGURE 5 The values of L T plotted against Tm3=2 2=3 Am7=6 for various semiconductors.

Some of the newer semiconductors that have been proposed as possible thermoelectric materials have relatively complex crystal structures with many atoms per unit cell. Such materials will have three acoustic modes and a very large number of optical modes. Moreover, the group velocity of the phonons is what is really important in Eq. (40), and this property varies greatly from mode to mode and from low to high frequency. It is generally likely to be much smaller for optical modes than for acoustic modes, so it is likely that most of the heat will be transported by acoustic phonons. It is, in fact, these phonons that are best approximated by the Debye model. Thus, in applying the Keyes relation to complex crystals, it is probably appropriate to regard a as the cube root of the volume of the unit cell. Also, Am should be regarded as the molecular weight. However, it is, perhaps, stretching Eq. (55) beyond the realm that Keyes had in mind when we apply it to complex materials. Nevertheless, it is still of some use when we are trying to select semiconductors of low thermal conductivity.

Sec. 5

REFERENCES

121

5. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26.

G. S. Nolas, J. Sharp, and H. J. Goldsmid Thermoelectrics: Basic Principles and New Materials Developments (Springer, Berlin, 2001). A. Sommerfeld, Z. Phys. 47, 1, 43 (1928). J. McDougall and E. C. Stoner Phil. Trans. A 237, 67 (1938). P. Rhodes Proc. R. Soc. A 204, 396 (1950). A. C. Beer, M. N. Chase, and P. F. Choquard Helv. Phys. Acta 28, 529 (1955). H. Fro«hlich and C. Kittel Physica 20, 1086 (1954). H. J. Goldsmid The Thermal Conductivity of Bismuth Telluride Proc. Phys. Soc. B 69, 203^209 (1956). J. W. Sharp, E. H. Volckmann, and H. J. Goldsmid The Thermal Conductivity of Polycrystalline Bi88 Sb12 ; Phys. Stat. Sol. (a) 185, 257^265 (2001). H. J. Goldsmid Heat Conduction in Bismuth Telluride Proc. Phys. Soc. 72, 17^26 (1958). Ya. Korenblit, M. E. Kuznetsov, V. M. Muzhdaba, and S. S. Shalyt Soviet Physics:JETP 30, 1009 (1969). C. Uher and H. J. Goldsmid Separation of the Electronic and Lattice Thermal Conductivities in Bismuth Crystals Phys. Stat. Sol. (b) 65, 765^771 (1974). P. Debye Ann. Phys. 39, 789 (1912). R. E. Peierls Ann. Phys. 3, 1055 (1929). A. Eucken Ann. Phys. 34, 185 (1911). J. Callaway Model for Lattice Thermal Conductivity at Low Temperatures Phys. Rev. 113, 1046^ 1051 (1959). J. E. Parrott The High Temperature Thermal Conductivity of Semiconductor Alloys Proc. Phys. Soc. 81, 726^735 (1963). T. H. Geballe and G. W. Hull Isotopic and Other Types of Thermal Resistance in Germanium Phys. Rev. 110, 773^775 (1958). G. S. Nolas, T. J. R. Weakley, J. L. Cohn, and R. Sharma Structural Properties and Thermal Conductivity of Crystalline Ge Clathrates Phys. Rev. B 61, 3845^3850 (2000). D. G. Cahill, S. K. Watson, and R. O. Pohl Lower Limit to the Thermal Conductivity of Disordered Crystals Phys. Rev. B 46, 6131^6139 (1992). G. A. Slack The Thermal Conductivity of Nonmetallic Crystals, in Solid State Physics, edited by F. Seitz, D. Turnbull, and H. Ehrenreich (Academic Press, New York, 1979) pp. 1^17. H. B. G. Casimir Physica, 5, 495 (1938). H. J. Goldsmid and R. W. Penn Boundary Scattering of Phonons in Solid Solutions Phys. Lett. A 27, 523^524 (1968). H. J. Goldsmid, H. B. Lyon, and E. H. Volckmann Proc. 14th Int. Conf. on Thermoelectrics (St. Petersburg, 1955) pp. 16^19. G. Leibfried and E. Schlo«mann Nachr. Akad. Wiss. Go«ttingen, Kl. 2 Math-Phys. 2, 71 (1954). J. S. Dugdale and D. K. C. MacDonald Latttice Thermal Conductivity, Phys. Rev. 98, 1751^1752 (1955). R. W. Keyes High Temperature Thermal Conductivity of Insulating Materials: Relationship to the Melting Point Phys. Rev. 115, 564-567 (1959).

Chapter 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS G. S. Nolas Department of Physics, University of South Florida, Tampa, FL, USA

J. Yang Materials and Processes Laboratory, General Motors R&D Center, Warren, MI, USA

H. J. Goldsmid School of Physics, University of New South Wales, Sydney, NSW, Australia

1. INTRODUCTION The theory of heat conduction in semiconductors was reviewed in Chapter 1.4 and some of the experimental observations have been used as illustrations. In this chapter the main emphasis is the behavior of materials emerging for practical applications, particularly in the ¢eld of thermoelectric energy conversion. The thermoelectric ¢gure of merit Z is de¢ned as 2 =, where is the Seebeck coe⁄cient, is the electrical conductivity, and is the thermal conductivity. Very often, the ¢gure of merit is used in its dimensionless form, ZT. Also, the ¢gure of merit is seen to be the ratio of the so-called power factor, 2 , to the thermal conductivity, . The electronic contribution to the thermal conductivity, e , is related to the electrical conductivity, as shown in Chap. 1.4. Thus, a good thermoelectric material combines a high power factor with a small value for the lattice conductivity, L :1 It is not surprising, therefore, that a great deal of e¡ort has been devoted to the search for materials with a low lattice conductivity. The substances reviewed in this chapter largely re£ect the results of this search.

124

Chap. 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

In the next section we brie£y summarize the observations made on thermoelectric materials already used in Peltier coolers and electric generators. These materials include alloys of bismuth and antimony, which are useful at low temperatures; alloys based on bismuth telluride, which are the mainstay of the thermoelectrics industry ; and the IV^VI compounds and the Si^Ge alloys, which are used in thermoelectric generation. In subsequent sections we discuss skutterudites, clathrates and half-Heusler compounds that continue to be of interest for thermoelectrics, and review some novel oxides and chalcogenides. 2. ESTABLISHED MATERIALS 2.1. Bismuth Telluride and Its Alloys Bismuth telluride (Bi2 Te3 ), has a layered structure with strongly anisotropic mechanical properties. There are two equivalent a axes and a mutually perpendicular c axis. In the direction of the c axis, the atomic planes follow the sequence Te^Bi^Te^ Bi^Te, which is then repeated. The Te^Te layers are held together by weak van der Waals forces, while the remaining atoms are linked by strong ionic^covalent bonds2 . Single crystals of bismuth telluride can be cleaved readily in the plane of the a axes. Not surprisingly, the transport properties, including the electronic and lattice thermal conductivities, are anisotropic. The electronic component of the thermal conductivity is anisotropic because the electrical conductivity is di¡erent in the a and c directions. The ratio of this quantity in the a direction to that in the c direction is larger for n-type material than for p-type material. It is somewhat larger than the ratio of the lattice conductivities in the two directions, which is reliably reported to be equal to 2.1, although the ready cleavage of bismuth telluride makes measurements of any transport properties in the c direction rather di⁄cult.3 In all samples of bismuth telluride, the two components of the thermal conductivity are of comparable magnitude. It is possible to calculate the electronic component from the measured electrical conductivity. However, the calculation is not so simple as it would be for a metal because the samples are usually only partly degenerate, so account must be taken of both the scattering law for the charge carriers and the position of the Fermi level (see Chapter 1.4). This being so, it is probably best to determine the lattice conductivity by extrapolation of the total thermal conductivity for samples of di¡ering carrier concentrations. Such an extrapolation must make use only of extrinsic samples because of the large bipolar contribution for mixed or intrinsic conduction. Figure 1 shows how the lattice conductivity of bismuth telluride along the cleavage planes varies with temperature.4 6 At high-temperatures, L varies as 1/T , but as the temperature falls there is a maximum value of about 60 W/m-K at about 10 K. It has been suggested that the position of the maximum depends on boundary scattering, but it may also be associated with point^defect scattering. Even in chemically pure samples, there are numerous defects due to the inherent nonstoichiometry of bismuth telluride. Bismuth telluride has been largely replaced as a material for thermoelectric refrigeration by its alloys with isomorphous compounds, bismuth selenide (Bi2 Se3 ) and antimony telluride (Sb2 Te3 ). The study of these materials followed the sugges-

Sec. 2

ESTABLISHED MATERIALS

125

FIGURE 1. Lattice conductivity plotted against temperature for bismuth telluride in the plane of the a axes.3 5

κ L(W m-1 K -1)

tion by Io¡e et al.7 that the formation of a solid solution could reduce the lattice conductivity without lowering the carrier mobility. It was indeed found that this was the case for p-type material in the bismuth-antimony telluride system. Figure 2 shows plots obtained by 3 sets of workers for the lattice conductivity in the a direction at 300 K against composition.8 10 The di¡erence between the results is undoubtedly due to the techniques used to determine the electronic thermal conductivity, but in each case there is a clear minimum at a composition close to Bi0:5 Sb1:5 Te3 . Since the power factor for this alloy is virtually the same as it is for bismuth telluride, its advantage for thermoelectric applications is obvious. An even greater reduction in lattice conductivity occurs when bismuth selenide is added to bismuth telluride and the resultant solid solutions are commonly used as

et al.

Sb2Te3 (mol.%) FIGURE 2. Lattice thermal conductivity for solid solutions between Bi2 Te3 and Sb2 Te3 at 300 K. The measurements were made along the cleavage planes. (Reprinted from Ref. 1. Copyright 2001, SpringerVerlag.)

126

Chap. 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

n-type thermoelements. However, in this case, there is a reduction in the electron mobility, and for this reason the useful alloys are restricted to the compositions Bi2 Te3 x Sex with x < 0.6. 2.2. Bismuth and Bismuth^Antimony Alloys Alloys based on bismuth telluride may be used for thermoelectric refrigeration at low-temperature, but the dimensionless ¢gure of merit falls o¡ quite rapidly as the temperature is reduced. This would be the case even if Z were independent of temperature, but in fact, this quantity itself becomes smaller as T becomes less because of an increase in the lattice conductivity. The lattice conductivity does not vary so rapidly with temperature for the solid solutions as it does for the pure compound, but ZT nevertheless varies more rapidly than 1/T . There are actually signi¢cantly superior n-type materials below about 200 K, namely the alloys of bismuth with antimony. Bismuth itself is a semimetal so that, although it displays a large power factor, the total thermal conductivity is also large and the ¢gure of merit is not particularly high. However, the addition of up to about 15% of antimony causes a band gap to appear.11 The gap is too small to allow the alloys to be used in thermoelectric applications at ordinary temperatures, but it becomes the best n-type material as the temperature is reduced.12 The lattice conductivity is less for Bi^Sb alloys than it is for pure bismuth, which also helps increase the ¢gure of merit. Bismuth and Bi^Sb crystals have the same structure as those of bismuth telluride and display a similar anisotropy of the thermal conductivity and other properties. They are also characterized by high values of the electron mobility, especially at low

κ L(W m-1 K -1)

T/K

FIGURE 3. Total thermal conductivity and the lattice contribution in the binary direction plotted against the reciprocal of the temperature for pure bismuth. The electronic component has been determined by the procedure outlined in Chap. 1.4.14 (Reprinted from Ref. 1. Copyright 2001, SpringerVerlag.)

Sec. 2

ESTABLISHED MATERIALS

127

temperatures. The application of a transverse magnetic ¢eld may be used not only to improve the thermoelectric ¢gure of merit13 but also in the separation of the lattice and electronic components of the thermal conductivity,14 as described in Chap. 1.4. Figure 3 shows how the total thermal conductivity and the lattice component vary with temperature for pure bismuth. Some indication of the way in which the lattice conductivity falls as the concentration of antimony is increased in Bi^Sb alloys is given in Figure 4. Here the variation of the total thermal conductivity in the binary direction is plotted against the strength of the magnetic ¢eld in the bisectrix direction for three di¡erent alloys.15 The measurements were made at 80 K, at which temperature the ¢eld e¡ects are much stronger than at 300 K. In a ¢eld of 1 T there is very little remaining of the electronic contribution to the thermal conductivity. The Nernst^ Ettingshausen ¢gure of merit is not particularly large for the given ¢eld orientation, so the thermal conductivity does indeed tend toward the lattice component at high magnetic ¢eld strengths. Note that the lattice conductivity of pure bismuth at 80 K is about 17 W/m-K and that the addition of no more than 3% antimony is su⁄cient to reduce L by a factor of more than 3. 2.3. IV^VI Compounds The bismuth telluride solid solutions become less e¡ective as thermoelectric materials when the temperature is raised much above, say, 400 K. This is mainly because the energy gap is only about 0.3 eV so that there are a signi¢cant number of minority carriers present at higher temperatures. The minority carriers give rise to a thermoelectric e¡ect, which opposes that of the majority carriers. Lead telluride (PbTe) and other compounds between Group IV and Group VI elements have somewhat larger energy gaps, and, therefore, the onset of mixed conduction occurs at rather larger temperatures. In many ways lead telluride is an easier material to work with than bismuth telluride. In particular, it has the cubic sodium chloride structure and, as a result,

κ L(W m-1 K -1)

8

FIGURE 4. Thermal conductivity plotted against magnetic ¢eld for certain bismuth^antimony alloys at 80 K.15 The temperature gradient is in the binary direction, and the magnetic ¢eld is in the bisectrix direction. (Reprinted from Ref. 1. Copyright 2001, Springer-Verlag.)

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the basic transport properties are the same in all directions. The combination of a rather high mobility with a small e¡ective mass for both electrons and holes16 gives a power factor of the same order as that for bismuth telluride. However, at room temperature the lattice conductivity is 2.0 W/m-K and the ¢gure of merit is smaller for the lead compound. Above 200‡C the larger energy gap is su⁄cient compensation for the higher lattice conductivity, and lead telluride is the superior thermoelectric material. In fact, it is preferable to use lead telluride solid solutions rather than the simple compound. Airapetyants et al.17 observed a reduction of the lattice conductivity on adding tin telluride (SnTe) or lead selenide (PbSe) to lead telluride. Pb1 y Sny Te is still regarded as one of the most useful p-type thermoelectric materials up to perhaps 800 K, but quaternary alloys have been used as an n-type material in preference to a solid solution based on lead telluride. The quaternary alloys have been given the acronym TAGS since they contain the elements Te, Ag, Ge, and Sb. They are essentially alloys between AgSbTe2 and GeTe, and for certain ranges of composition they share the sodium chloride structure with PbTe. When the concentration of GeTe falls below about 80%, the alloys take on a rhombohedral structure. For compositions lying close to that of the phase transformation there is considerable lattice strain, and it is believed that this may be the reason for exceptional low values of thermal conductivity in this region.18 This is illustrated by the plots of lattice conductivity against the reciprocal of the temperature for PbTe^SnTe and so-called TAGS-85 (Fig. 5). The latter material contains 85% GeTe. 2.4. Silicon, Germanium, and Si^Ge Alloys Silicon is remarkable in that, though it is nonmetallic, it has a thermal conductivity comparable with that of many metals. The need for large and perfect crystals of

FIGURE 5. Plots of lattice conductivity against the reciprocal of the temperature for PbTe-SnTe and TAGS-85.18

Sec. 3

SKUTTERUDITES

129

high-purity silicon for the electronics industry has made available excellent samples for basic thermal conductivity studies. Its high thermal conductivity makes silicon of little use as a thermoelectric material. Germanium, also has a rather large thermal conductivity, but silicon^germanium alloys have been used for high-temperature thermoelectric generation. The lattice conductivities of silicon and germanium at 300 K are 113 and 63 W/m-K, respectively, but Si0:7 Ge0:3 has a value of only about 10 W/m-K.19 Silicon, germanium, and Si^Ge alloys all possess the cubic diamond structure, and their thermal and electrical conductivities do not depend on crystal orientation. Thus, in principle, randomly oriented polycrystalline samples should be just as good as single crystals in thermoelectric applications. In fact, there have been claims that ¢ne-grained polycrystals are superior because of a reduction of the thermal conductivity through boundary scattering of the phonons.20 This exempli¢es the principles discussed in Sec. 2.3 of Ch. 1.4. Although the mean free path of the charge carriers is undoubtedly higher than that of the phonons in Si^Ge alloys, the preferential scattering of the low-frequency phonons by the grain boundaries can lead to a greater reduction of the lattice conductivity than of the carrier mobility.21 Boundary scattering at room temperature has been observed for thin samples of single-crystal silicon, the e¡ect being enhanced by introducing, through neutron irradiation, phononscattering point defects.22 One of the most interesting experiments on the thermal conductivity of solids was carried out by Geballe and Hull.23 They were able to obtain a single crystal of germanium in which the isotope Ge74 had been enriched to 96%. They compared the thermal conductivity of this crystal with that of another crystal in which the isotopes had their naturally occurring distribution. As shown in Fig. 6, the thermal conductivity of the isotopically enriched sample was signi¢cantly higher at all temperatures and about 3 times as large at 20 K. The results are remarkable in that the two crystals were virtually indistinguishable in most of their physical properties. Nevertheless, the behavior is in substantial agreement with the theory of massdefect scattering of phonons that was outlined in Sec. 2.2. 3. SKUTTERUDITES Skutterudite compounds have been extensively studied as potential high-e⁄ciency thermoelectric materials in recent years. The chemical formula for binary skutterudites is MX3 , where the metal atom M can be Co, Ir, or Rh, and the pnicogen atom X can be P, As, or Sb. Binary skutterudite compounds crystallize in a bodycentered-cubic structure with space group Im3, and the crystal structure contains large voids at the a positions (12-coordinated); each M atom is octahedrally surrounded by X atoms, thus forming a MX6 octahedron. They are semiconductors with small band gaps (100 meV), high carrier mobilities, and modest thermopowers. Detailed structural and electronic properties can be found in two reviews.24;25 CoSb3 -based skutterudites have particularly been the focal point of research mainly because of the abundance of the constituent elements. Despite their excellent electronic properties, they possess thermal conductivities (10 W/m-K at room temperature) that are too high to compete with state-of-the-art thermoelectric materials. Partially ¢lled skutterudites Gy M4 X12 are formed by inserting small guest ions into the large 12-coordinated sites of binary skutterudites, where G represents a guest ion and y is its ¢lling fraction. The maximum ¢lling fraction ymax varies

130

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SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

10000

κ

Enriched Ge74

(W m-1 K-1 ) 1000 Normal Ge

100

10 1

10

7 (K)

100

FIGURE 6. Thermal conductivity of normal germanium and enriched Ge74 .23

depending on the valence and the size of the guest ion. By replacing M or X with electron-de¢cient elements, one can attain full ¢lling of the voids. These guest ions often have large thermal parameters. It was suggested that these guest ions or ‘‘rattlers’’ may strongly scatter the heat carrying lattice phonons in the low-frequency region, thereby, very e¡ectively reducing the lattice thermal conductivities of the parent binary skutterudite compounds.26 These low-frequency phonons are otherwise di⁄cult to be scattered by conventional methods. Low lattice thermal conductivities over a wide temperature range subsequently observed in ¢lled skutterudites led to ZT well above 1.0 between 500 K and 1000 K.27 33 It is evident that ¢lling the crystal structure voids results in a dramatic decrease of the lattice thermal conductivity of skutterudites; the e¡ect of doping is equally dramatic and bene¢cial.28;29;34;35 A very important feature of skutterudites is the large number of di¡erent isostructural compositions that can be synthesized. The diversity of potential compositional variants remains one of the key reasons why this material system continues to be investigated by many research groups. 3.1. Binary (Un¢lled) Skutterudites Figure 7 shows lattice thermal conductivity L as a function of temperature for single-crystal CoSb3 , polycrystalline CoSb3 , polycrystalline IrSb3 , and polycrystalline Ru0:5 Pd0:5 Sb3 .36 Also included are the room temperature data for PtSb2 and RuSb2 and the calculated minimum thermal conductivity for IrSb3 . The minimum thermal conductivity min is calculated by taking the minimum mean free path of the acoustic phonons as one half of the phonon wavelength. For single-crystal CoSb3 37 at low temperatures, L is about two orders of magnitude higher than that of polycrystalline CoSb3 .38 This is attributed to the di¡erences in the grain size

Sec. 3

SKUTTERUDITES

131

Temperature (K) FIGURE 7. Lattice thermal conductivity versus temperature for single-crystal CoSb3 , polycrystalline CoSb3 , polycrystalline IrSb3 , and polycrystalline Ru0:5 Pd0:5 Sb3 .36 Also included are the room temperature data for PtSb2 and RuSb2 , and the calculated minimum thermal conductivity min for IrSb3 .36;38 (Reprinted from Ref. 36. Copyright 1996, American Institute of Physics.)

and the amount of defects between the two. At high temperatures L for singlecrystal CoSb3 decreases exponentially with increasing temperature, indicative of the predominant phonon^phonon umklapp scattering and sample quality. At room temperature L ’s of the single-crystal and polycrystalline CoSb3 approach a common value. The overall L for polycrystalline IrSb3 is somewhat higher than that of polycrystalline CoSb3 , despite Ir having a higher atomic mass than Co. The room temperature L of Ru0:5 Pd0:5 Sb3 is about a factor of 5 smaller than the binary skutterudite compounds, and the di¡erence is even greater at low temperatures. The room temperature data for PtSb2 and RuSb2 are also plotted for comparison. None of these binary compounds has room temperature L as low as Ru0:5 Pd0:5 Sb3 . A NEXAFS (near-edge extended absorption ¢ne structure) study and a simple electron count reveal that Ru is in a mixed valence state, and a correct composition 4þ 2þ can be written as ‘ Ru2þ x Ruy Pdz Sb3 , where ‘ represents a vacancy on the metal 36 site. A mass £uctuation with strain ¢eld correction estimation for L is not su⁄cient to reproduce the data at room temperature. The low L is ascribed to additional phonon scattering by a rapid transfer of electrons between the d shells of Ru2þ and Ru4þ .

132

Chap. 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

3.2. Effect of Doping on the Co Site

κ L(W m-1 K -1)

The conductivity L can also be signi¢cantly suppressed upon doping transition metal elements on the Co site.38 40 Figure 8 shows the temperature dependence of L between 2 K and 300 K for Co1 x Fex Sb3 . Iron doping dramatically decreases the overall L . At the L peak a reduction of about an order of magnitude is observed from CoSb3 to Co0:9 Fe0:1 Sb3 . The additional strain (6%) and mass (5%) £uctuations introduced by alloying Fe on the Co site simply could not account for the observed L reduction. The experimental data are modeled by the Debye approximation, including phonon-boundary, phonon^point-defect, and phonon^phonon umklapp scatterings.38 In Fig. 8 the solid and dashed lines represent theoretical ¢ts for CoSb3 and Co0:9 Fe0:1 Sb3 , respectively. The agreement between calculations and experimental data is very good. It is found that phonon^point-defect scattering prefactor increases by a factor of about 25 from CoSb3 to Co0:9 Fe0:1 Sb3 , indicating a rapid increase of point-defect concentration upon Fe alloying on the Co site. Based on the thermal conductivity and study of other low-temperature transport properties, the increased Fe doping is believed to signi¢cantly increase the amount of vacancies with severed atomic bonds on the Co site which leads to strong scattering of the lattice phonons. This is reasonable in light of the eventual instability of the skutterudite structure at higher Fe concentration and the lack of existence of a FeSb 3 phase. Recently reported electron tunneling experiments on Co1 x Fex Sb3 suggest that the observed strong zero-bias conductance anomaly arises from a structural disorder produced by vacancies on the Co sites, in agreement with analysis.41 Figure 9 displays the temperature dependence of L from 2 K to 300 K for Co1 x Nix Sb3 samples, and it is clear that Ni doping strongly suppresses L . For very small Ni concentrations (x 0.003), L decreases rapidly with increasing x, and this e¡ect is especially manifested at low-temperature (T < 100 K). As the Ni

FIGURE 8. Lattice thermal conductivity of Co1 x Fex Sb3 versus temperature. The solid and dashed lines represent calculations based on the Debye approximation.39 (Reprinted from Ref. 39. Copyright 2001, American Physical Society.)

Sec. 3

SKUTTERUDITES

133

concentration increases, the suppression of L seems to saturate. The lines are drawn to illustrate the T a dependence of L at low-temperature (T < 30 K), where a = 2.08, 1.22, and 1 for x = 0, x = 0.001, and x 0.003, respectively. The observation that L / T 1 for T < 30 K for all x 0.003 samples is a strong indication of the presence of electron^phonon interaction.38 From analysis of electrical transport and magnetic data, it is found that electrical conduction at lowtemperature (less than 30 K) is dominated by hopping of electrons among the impurity states.42 The electron mean free path is estimated to be about 109 m, which is much shorter than the estimated phonon wavelength 108 m for T < 30 K.38 The electron^phonon interaction is included in the theoretical ¢ts (Debye approximation) for the data in addition to the phonon-boundary, phonon^pointdefect, and phonon^phonon umklapp scatterings. The theoretical model ¢ts the experimental data very well from 2 K to 300 K.38 It is concluded that the reduction in L (especially at low temperature) is the result of strong electron^phonon interaction between very-heavy-impurity electrons and lattice phonons. Doping on the Co site of CoSb3 with transition-metal elements signi¢cantly suppresses heat conduction in these binary skutterudites. This partially accounts for the high values of the ¢gure of merit obtained in both p-type and n-type ¢lled skutterudites.28;42 3.3. Filled Skutterudites

κ L(W m-1 K -1)

One of the most important ¢ndings of the recent skutterudite studies is the e¡ect of guest ion ¢lling of the large interstitial voids on L . The guest ions are enclosed in an irregular dodecahedral cage of X atoms. Based on the large x-ray thermal parameters of these ions, Slack suggested that, if smaller than the voids, the guest

FIGURE 9. Temperature dependence of the lattice thermal conductivity of Co1x Nix Sb3 between 2 K and 300 K. The lines indicate L / T 2:08 , T 1:22 , and T 1 between 2 K and 30 K for x = 0, 0.001, and 0.003, respectively.38 (Reprinted from Ref. 38. Copyright 2002, American Physical Society.)

134

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SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

ions may rattle and therefore interact with lattice phonons, resulting in substantial phonon scattering.26 The most direct evidence of rattling comes from the atomic displacement parameters (ADPs, a.k.a. thermal parameters) obtained from either xray or neutron scattering of single crystals. The isotropic ADP, Uiso , represents the mean square displacement average over all directions.43 Figure 10 shows the temperature dependence of Uiso between 10 K and 300 K for RFe4 Sb12 (R = Ce, La, and Yb). The ADP values for Fe and Sb are typical for these elements in compounds with similar coordination numbers, whereas those for Ce, La, and Yb are anomalously large, particularly at high-temperatures. These results suggest that the guest ions are loosely bonded in the skutterudite structure and rattle about their equilibrium positions. It is also interesting to notice that Uiso increases as the ion size decreases from Ce to Yb. The demonstration of thermal conductivity reduction over a wide temperature range due to ¢llers (or rattlers) was ¢rst realized in Ce-¢lled skutterudites.27 Subsequently, similar e¡ects were observed in skutterudites ¢lled with La, Tl, Yb, Ba, and Eu.29 33 Figure 11 shows the temperature dependence of L for un¢lled IrSb3 , La, Sm, and Nd-¢lled IrSb3 .44 The calculated min for IrSb3 is also plotted. Upon rare-earth ¢lling, L is reduced by more than an order of magnitude over most of the temperature range. The temperature dependence of L is signi¢cantly altered by rare-earth ¢lling as well. The dielectric peak of L that is evident for IrSb3 completely disappears for the ¢lled skutterudite samples. The Sm and Nd ions are smaller than La ions and therefore are freer to rattle inside the voids. They are believed to interact with lower-frequency phonons as compared to La ions, leading to a larger L reduction. Furthermore, the low-lying 4f electronic energy levels of Sm and Nd ions also produce additional phonon scattering. Since the ground state of Nd ions splits into more levels of smaller energy separation than that of Sm ions,

0.025

RFe4Sb12 (R=La, Ce, and Yb)

Uiso (Å2)

0.020

Yb Ce

0.015

La 0.010

Sb 0.005

Fe

0.000

0

50

100

150

200

250

300

350

T (K) FIGURE 10. Isotropic atomic displacement parameters Uiso for RFe4 Sb12 (R = La, Ce, Yb) alloys.

SKUTTERUDITES

135

κ L(W m-1 K -1)

Sec. 3

FIGURE 11. Lattice thermal conductivity versus temperature for the La-, Sm-, and Nd-¢lled skutterudite samples as well as the un¢lled IrSb3 sample. The calculated values of min for IrSb3 are also included.44 (Reprinted from Ref. 44. Copyright 1996, American Institute of Physics.)

Nd ions will scatter a larger spectrum of phonons than will Sm ions. This e¡ect should be manifested at low temperatures because these phonons have long wavelengths. As shown in Fig. 11, at room temperature, L of Nd-¢lled and Sm-¢lled samples are about the same. At 10 K, L of the former is only about half that of the latter. The ¢lling fraction y of the ¢lled skutterudites can normally be increased by replacing electron-de¢cient elements on the M or X sites. In the case of Ce-¢lled skutterudites, Fe alloying on the Co site not only alters the optimal Ce ¢lling fraction, the location of the Fermi level, carrier type, and carrier concentration,45 but also strongly a¡ects the nature of the phonon scattering of the optimally Ce¢lled skutterudites.46 In a series of optimally Ce-¢lled skutterudite samples, Meisner et al.46 found that L ¢rst decreases with increasing Ce ¢lling fraction, reaches a minimum, and then increases for higher Ce ¢lling fractions. This anomalous e¡ect is justi¢ed by considering these Ce-¢lled skutterudites as solid solutions of CeFe4 Sb12 (fully ¢lled) and ‘ Co4 Sb12 (un¢lled), where ‘ denotes a vacancy. The predominant phonon^point^defect scattering does not arise between Co and Fe, but between Ce and ‘. Figure 12 plots the room temperature thermal resistivity of (CeFe4 Sb12 Þ (‘ Co4 Sb12 Þ1 as a function of . The solid line represents a theoretical calculation for the thermal resistivity of these solid solutions. The dashed line includes additional thermal resistivity arising from other phonon scatterings. This solid solution model explains the variation of L very well without even a single adjustable parameter.46 The interaction between the lattice phonons and the rattlers can be modeled by a phonon resonance scattering term in the Debye approximation. Figure 13 shows the experimental L data with theoretical ¢ts (solid lines) for CoSb3 , Yb0:19 Co4 Sb12 , and Yb0:5 Co4 Sb11:5 Sn0:5 .47 The theoretical ¢t for CoSb3 is calculated with the De-

136

Chap. 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

κ L(W m-1 K -1)

FIGURE 12. Variation of the thermal resistivity of (CeFe4 Sb12 Þ ð‘ Co4 Sb12 Þ1 solid solutions as a function of at room temperature. Dashed line represents variation from the rule of mixtures. Solid line includes calculated additional thermal resistivity due to the formation of solid solutions.46 (Re-printed from Ref. 46. Copyright 1998, American Physical Society.)

FIGURE 13. Temperature dependence of the lattice thermal conductivity for CoSb3 , Yb0:19 Co4 Sb12 , and Yb0:5 Co4 Sb11:5 Sn0:5 . The symbols are the experimental data, and the solid lines represent a calculation based on the Debye approximation.47

Sec. 4

CLATHRATES

137

bye approximation and assuming only the boundary, point-defect and umklapp scatterings. An additional phonon^resonant scattering term is included in the model for the calculations of the Yb-¢lled samples. The solid lines ¢t the experimental data very well for all three samples over the entire two orders of magnitude temperature span. Yang et al.47 ¢nd that the predominant phonon^point-defect scattering in these samples is on the Yb sites between Yb and ‘, and the phonon-resonant scattering increases linearly with increasing Yb ¢lling fraction in agreement with theory. 4. CLATHRATES Compounds with the clathrate crystal structure display an exceedingly rich number of physical properties, including semiconducting behavior, superconductivity, and thermal properties reminiscent of amorphous materials. All of these properties are a direct result of the nature of the structure and bonding of these materials.48 Clathrate compounds form in a variety of di¡erent structure types. They are basically Si, Ge, and Sn network structures or three-dimensional arrays of tetrahedrally bonded atoms built around various guests. The majority of work thus far on the transport properties of clathrates has been on two structure types that are isotypic with the clathrate hydrate crystal structures of type I and type II. The type I clathrate structure can be represented by the general formula X2 Y6 E46 , where X and Y are alkali-metal, alkaline earth, or rare-earth metal ‘‘guest’’ atoms that are encapsulated in two di¡erent polyhedra and E represents the Group IV elements Si, Ge, or Sn (although Zn, Cd, Al, Ga, In, As, Sb, or Bi can be substituted for these elements to some degree). Similarly, the type II structure can be represented by the general formula X8 Y16 E136 .48 As shown in Fig. 14, these structures can be thought of as being constructed from two di¡erent face-sharing polyhedra; two pentagonal dodecahedra (E20 Þ and 6 tetrakaidecahedra (E24 Þ per unit cell in the case of the type I structure, and 16 dodecahedra (E20 Þ and 8 hexakaidecahedra (E28 Þ for type II compounds. The guest^host interaction is one of the most conspicuous aspects of these compounds and directly determines the variety of interesting and unique properties

FIGURE 14. Type I (left) and type II (right) clathrate crystal structures. Only group 14 elements are shown. Outlined are the two di¡erent polyhedra that form the unit cell. (Reprinted from Ref. 1. Copyright 2001, Springer-Verlag.)

Chap. 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

κ L(W m-1 K -1)

138

FIGURE 15. Lattice thermal conductivity versus temperature for polycrystalline Sr8 Ga16 Ge30 , singlecrystal Ge, amorphous SiO2 , and amorphous Ge. The straight-line ¢t to the Sr8 Ga16 Ge30 data below 1 K produces a T 2 temperature dependence characteristic of glasses.

these materials possess. One of the more interesting of these properties is a very distinct thermal conductivity. For example, the thermal conductivity of semiconductor Sr8 Ga16 Ge30 shows a similar magnitude and temperature dependence to that of amorphous materials.49 51 In fact at room temperature the thermal conductivity of these compounds is lower than that of vitreous silica and very close to that of amorphous germanium (Fig. 15). The low-temperature (< 1 K) data indicate a T 2 temperature dependence, as shown by the straight-line ¢t to the data in Fig. 15. Higher-temperature data show a minimum, or dip, indicative of resonance scattering. This resonance ‘‘dip’’ is more pronounced in single-crystal specimens, since scattering from grain boundaries is not a factor in these specimens.49 51 It is clear from these results that in the Sr8 Ga16 Ge30 compound the traditional alloy phonon scattering, which predominantly scatters the highest-frequency phonons, has been replaced by one or more much lower frequency scattering mechanisms. The scattering of the low-frequency acoustic phonons by the ‘‘rattle’’ modes of the encapsulated Sr atoms results in low thermal conductivity. We note that this glasslike thermal conductivity is found in semiconducting compounds that can be doped, to some extent, in order to vary their electronic properties.49 This result indicates why these materials are of speci¢c interest for thermoelectric applications. The transport properties are closely related to the structural properties of these interesting materials, as discussed later. Figure 16 shows the lattice thermal conductivity of several type I clathrates. Semiquantitative ¢ts to these data as well as recent resonant ultrasound spectroscopic studies52 indicate the existence of low-frequency vibrational modes of the ‘‘guest’’ atoms inside their oversized polyhedra. Lowfrequency optic ‘‘rattle’’ modes were theoretically predicted to be well within the framework acoustic phonon band.53 A Raman spectroscopic analysis of several type I clathrates experimentally veri¢ed these results.54 The correlation between the thermal, ultrasound, and optical properties with the structural properties, as well as recent theoretical analysis,55 is strong evidence that the resonance scattering

CLATHRATES

139

κ L(W m-1 K -1)

Sec. 4

FIGURE 16. Lattice thermal conductivity of ¢ve representative polycrystalline type I clathrates. The dashed and dotted curves are for amorphous SiO2 and amorphous Ge, respectively, and the solid curve is the theoretical minimum thermal conductivity calculated for diamond-Ge. (Reprinted from Ref. 50. Copyright 1999, American Physical Society.)

of acoustic phonons with the low-frequency optical ‘‘rattle’’ modes of the ‘‘guest’’ atoms is a strong phonon scattering process in clathrates. Room temperature structural re¢nements from single-crystal and powder neutron scattering and x-ray di¡raction reveal large atomic displacement parameters (ADPs) for atoms inside the tetrakaidecahedra as compared to the framework atoms of the type I clathrates. This is an indication of localized disorder within these polyhedra beyond typical thermal vibration. This is illustrated in Fig. 17a, where the ADPs of the Sr(2) (i.e., Sr inside the tetrakaidecahedra) exhibit an anisotropic ADP that is almost an order of magnitude larger than those of the other constituents in Sr8 Ga16 Ge30 .51;56 Large and anisotropic ADPs are typically observed for relatively small ions in the tetrakaidecahedra in this crystal structure. The enormous ADP for the Sr(2) site implies the possibility of a substantial dynamic or ‘‘rattling’’ motion. It is also possible to correlate these ADPs with a static disorder in addition to the dynamic disorder. The electrostatic potential within the polyhedra is not everywhere the same, and di¡erent points may be energetically preferred. The ADP data can then also be described by splitting the Sr(2) site into four equivalent positions, as shown in Fig. 17b. This would suggest that these Sr atoms may tunnel between the di¡erent energetically preferred positions. The possibility of a ‘‘freeze-out’’ of the ‘‘rattle’’ modes of Sr in Sr8 Ga16 Ge30 was initially postulated by Cohn et al.50 from low-temperature thermal conductivity data (see Fig. 15). The ‘‘split-site’’ model was very eloquently revealed by Chakoumakos et al.56 , who employed temperature-dependent neutron di¡raction data on single-crystal and powder Sr8 Ga16 Ge30 , where the split-site (static + dynamic) model and the single-site (dynamic disorder) model are clearly distinguished. These results clearly illustrate how the speci¢c framework and thermal parameters associated with the atoms in these compounds are an important aspect of this structure and have an e¡ect on the transport properties.48 It also shows the unique properties thus far revealed in type I clathrates. Moreover, many di¡erent compositions have been synthesized in investigating the thermal properties of these interesting materials.

140

Chap. 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

a. M1

Sr2

Sr1 M3 M2

M1

b.

Sr2

FIGURE 17. Crystal structure projection on a (100) plane of Sr8 Ga16 Ge30 illustrating the large anisotropic atomic displacement parameters for the single-site model (a) and the split-site model (b) where the combined static and dynamic disorder of the Sr(2) crystallographic site with isotropic atomic displacement parameters is indicated. (Reprinted from Ref. 56. Copyright 1999, Elsevier Science.)

Fig. 17 illustrates this by showing the thermal conductivity of several type I clathrates. Unlike type I clathrate compounds, type II clathrates can be synthesized with no atoms inside the polyhedra that form the framework of the crystal structure. Gryko et al.57 have synthesized Si136 and demonstrated it is a clathrate form of elemental silicon with a 2-eV band gap and semiconducting properties. This experimental result veri¢ed the theoretical prediction made by Adams et al.58 The thermal conductivity of Si136 shows a very low thermal conductivity, as shown in Fig. 18.59 The room temperature thermal conductivity is comparable to that of amorphous silica and 30 times lower from that of diamond structure Si. The temperature dependence, however, is quite di¡erent from that of a-SiO2 . Indeed the temperature dependence of Si136 at low temperatures does not follow the glasslike behavior characteristic of a-SiO2 . This again con¢rms that the low value of L is an intrinsic property of Si136 . The solid line in Fig. 18 illustrates the trend toward a T 3 dependence at the lower temperatures, where scattering from grain boundaries will dominate. As seen in the ¢gure the lowest-temperature L data begin to follow this temperature dependence. Again, this is di¡erent from Sr8 Ga16 Ge30 , for example, where a T 2 dependence is observed at low temperatures due to the localized disorder of Sr inside the (Ga,Ge) polyhedra. The low thermal conductivity suggests that Si136 is another low-thermal-conductivity semiconductor. It may be that in this framework optic modes play an important role in the thermal conduction of this compound and, indeed, type II

HALF-HEUSLER COMPOUNDS

141

κ L(W m-1 K -1)

Sec. 5

FIGURE 18A. Lattice thermal conductivity as a function of temperature for polycrystalline Si136 and aSiO2 . The solid line indicates a temperature dependence of T 3 . (Reprinted from Ref. 59. Copyright 2003, American Institute of Physics.)

clathrates in general. The data imply a strong e¡ect on the thermal transport from the large number of atoms per unit cell in Si136 upon damping of the acoustic phonons by zone-edge singularities. The polyhedra are ‘‘empty’’ ; therefore, localized disorder is not the reason for the low thermal conductivity. The thermal conductivity for a ‘‘guest-free’’ clathrate (hypothetical type I Ge46 Þ was recently calculated by using a Terso¡ potential to mimic interatomic interactions.55 A 10fold decrease in lattice thermal conductivity compared with the diamondstructure semiconductor was noted due to scattering of heat carrying acoustic phonons by zone-boundary modes ‘‘folded back’’ due to the increase in unit cell size. The result indicates that low-thermal-conductivity values are achieved in clathrate compounds without ‘‘rattling’’ guest atoms, due to the intrinsic vibrational properties of the framework and the enlarged unit cell. 5. HALF-HEUSLER COMPOUNDS Half-Heusler compounds possess many interesting transport and magnetic properties. These compounds can be semiconductors, semimetals, normal metals, weak ferromagnets, antiferromagnets, or strong half-metallic ferromagnets. In particular, MNiSn (M = Ti, Zr, or Hf) half-Heusler compounds show promising thermoelectric characteristics. The MNiSn compounds are a subset of a much larger family of compounds possessing the so-called MgAgAs-type structure. This structure is cubic and consists of three interpenetrating fcc sublattices with an element of each type on each sublattice displaced by one fourth of the distance along the body diagonal.60 The fourth site along the body diagonal is not occupied and thus is an ordered array of vacancies. The MgAgAs-type structure is closely related to the MnCuAl2 -type structure in which this vacant position is occupied. The fully occupied structures, which in the MNiSn family are of the form MNi2 Sn, are metals known as Heusler compounds. Following this nomenclature, the MNiSn compounds are frequently termed half-Heusler compounds. The di¡erence between

142

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SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

the Heusler and the half-Heusler crystal structures, however, is not only in the ¢lling of a vacant site, but also involves a change of space group and a reordering of the atoms. The MNiSn compounds have the space group F 43m with four crystallographically inequivalent fourfold sites, M, Ni, Sn, and (the vacancy). In MNiSn, one published structure60 has the sequence M, Sn, Ni, and at positions (0,0,0), (1/ 4,1/4,1/4), (1/2,1/2,1/2), and (3/4,3/4,3/4), respectively. An alternative structure61 has the M and Sn positions reversed. Indeed, there may be substantial site-exchange disorder between M and Sn, particularly when M is Hf or Zr. While the full Heusler alloys are metals, many half-Heusler compounds are semiconductors with band gaps of about 0.21^0.24 eV:62;63 The large Seebeck coef¢cient, due to the heavy conduction band, and modestly large electrical resistivity make MNiSn compounds ideal candidates for optimization.64 67 Alloying Zr and Hf, Ti, and Zr on the M sites, we ¢nd that Pd on the Ni site leads to an overall reduction of the total thermal conductivity .63 65; 68 70 Doping 1 at.% Sb on the Sn site results in a lowering, by several orders of magnitude, of the resistivity without signi¢cantly reducing the Seebeck coe⁄cient, leading to peak power factors in excess of 35 W/cm-K2 between 675 K and 875 K for a number of doped halfHeusler compounds.63;64;68;70;71 The highest ZT value reported was 0.7 around 800 K for the Zr0:5 Hf0:5 Ni0:8 Pd0:2 Sn0:99 Sb0:01 compound.70 Doped half-Heusler compounds are prospective materials for high-temperature thermoelectric power generation. Thermal conductivities for these materials have to be further reduced (without lowering power factors) to make it a practical reality. 5.1. Effect of Annealing Since intermixing between M and Sn sublattices depends on the heat treatment, a series of measurements monitoring transport properties as a function of annealing conditions were made. Especially, the behavior of is extremely sensitive to the structural disorder and is thus a very good indicator of the evolving perfection of the crystal lattice.65 Figure 19 shows the temperature dependence of on ZrNiSn (panel a), HfNiSn (panel b), and Zr0:5 Hf0:5 NiSn (panel c) subjected to up to 1-week annealing periods. The transport properties remain stable beyond 1-week annealing. The electronic thermal conductivity component is estimated to be less than 1% of the total ; therefore, the data shown are almost entirely the lattice part. All samples show dramatic changes in with prolonged annealing. For ZrNiSn and HfNiSn, annealing enhances : This is especially manifested at low temperatures. After a week of annealing, the peak in (T) increases by about a factor of 3, suggesting an improvement in the structural quality of the annealed materials. Even though HfNiSn has higher thermal conductivity values at all temperatures and in all corresponding annealing stages than does ZrNiSn, the percentage increase in is about the same for both samples. Annealing, however, promotes an opposite trend in for Zr0:5 Hf0:5 NiSn : decreases upon annealing. This suggests that the as-cast sample does not have the M site completely randomized, and it takes heat treatment to ensure that the Zr and Hf atoms are completely mixed. 5.2. Isoelectronic Alloying on the M and Ni Sites Figure 19 also shows that the overall is much suppressed over the entire temperature range by isoelectronically alloying Zr and Hf on the M site. This is due to the phonon^point-defect scattering between Zr (atomic mass MZr = 91) and Hf

HALF-HEUSLER COMPOUNDS

143

κ (W m-1 K -1)

κ (W m-1 K -1)

κ (W m-1 K -1)

Sec. 5

κ (W m-1 K -1)

FIGURE 19. Thermal conductivity as a function of temperature for di¡erent annealing periods. (a) ZrNiSn; (b) HfNiSn; (c) Zr0:5 Hf0:5 NiSn.65 (Reprinted from Ref. 65. Copyright 1999, American Physical Society.)

FIGURE 20. Thermal conductivity as a function of temperature for one-week-annealed ZrNiSn, Zr0:5 Hf0:5 NiSn, and Zr0:5 Hf0:5 NiSn0:99 Sb0:01 .65 (Reprinted from Ref. 65. Copyright 1999, American Physical Society.)

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SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

(atomic mass MHf = 179). This e¡ect is better illustrated in Fig. 20, where the temperature dependence of for one-week-annealed ZrNiSn, Zr0:5 Hf0:5 NiSn, and Zr0:5 Hf0:5 NiSn0:99 Sb0:01 is plotted between 2 K and 300 K.65 At room temperature, decreases from 17.2 W/m-K for ZrNiSn to 5.3 W/m-K for Zr0:5 Hf0:5 NiSn, more than a factor of 3. There is also a slight thermal conductivity increase near room temperature by doping 1 at.% of Sb on the Sn site of Zr0:5 Hf0:5 NiSn. This is attributed to the increased electronic thermal conductivity as a consequence of an increased electron concentration upon Sb-doping.65 The thermal conductivity of ZrNiSn-based half-Heusler compounds is further reduced by simultaneously alloying Hf on the Zr site and Pd on the Ni site. A recent high-temperature thermoelectric property study of these materials shows that upon alloying 20 at.% of Pd on the Ni site, there is a reduction of by about a factor of 1.5 over the entire temperature range.70 This is the result of the phonon^ point-defect scattering between Ni (atomic mass MNi = 58.7) and Pd (atomic mass MPd = 106.4). Further reduction of is accomplished by alloying more (50 at.%) Pd on the Ni site, as illustrated in Fig. 21. At room temperature, = 4.5 and 3.1 W/ m-K for Zr0:5 Hf0:5 Ni0:8 Pd0:2 Sn0:99 Sb0:01 and Zr0:5 Hf0:5 Ni0:5 Pd0:5 Sn0:99 Sb0:01 , respectively. Increasing Pd alloying on the Ni site, however, decreases the overall power factor of these compounds.70 The highest ZT values are observed for n-type Zr0:5 Hf0:5 Ni0:8 Pd0:2 Sn0:99 Sb0:01 , not necessarily the compound with the lowest : 5.3. Effect of Grain Size Reduction

κ (W m-1 K -1)

At 800 K the highest ZT value achieved by half-Heusler compounds is 0.7. This is at least as good as the conventional high-temperature thermoelectric materials at

FIGURE 21. The e¡ect of Pd alloying on the Ni site on the thermal conductivity of Zr0:5 Hf0:5 NiSn0:99 Sb0:01 .70 (Reprinted from Ref. 70. Copyright 2001, American Institute of Physics.)

Sec. 6

NOVEL CHALCOGENIDES AND OXIDES

145

the same temperature; i.e., ZT 0.7 and 0.55 for PbTe and SiGe alloys, respectively. Future improvement in ZT will have to come from further reduction of . It was predicted that some improvement of ZT may be realized by reducing the grain sizes of the polycrystalline half-Heusler compounds.72 This is based on theoretical results suggesting that the lattice thermal conductivity decreases much faster than the carrier mobility with decreasing grain size for these materials. A recent experimental study shows a linear correlation between the room temperature lattice thermal conductivity and the average diameter of grains for Ti-based half-Heusler compounds,73 including ball-milled and shock-compacted samples with < 1 m grain sizes. The results are plotted in Fig. 22. The lattice thermal conductivity of these materials decreases with decreasing grain size. At room temperature, the ballmilled and shock-compacted sample exhibits a total thermal conductivity of about 5.5 W/m-K with a lattice component of about 3.7 W/m-K. Even though a subsequent study reports a disappointing power factor decrease upon decreasing the grain size of a TiNiSn0:95 Sb0:05 sample,74 a systematic investigation on the e¡ect of the grain size dependence of the power factor is much needed. 6. NOVEL CHALCOGENIDES AND OXIDES The thermal properties of complex chalcogenide and oxide compounds have recently been investigated in an e¡ort to expand the understanding of thermal transport in these materials to develop new materials for thermoelectric applications. In the last few years new compounds with interesting phonon scattering mechanisms that result in a low thermal conductivity have been investigated. In this section we review several of these compounds in terms of their thermal conduction.

FIGURE 22. Lattice thermal conductivity versus average grain diameter of TiNiSn1 x Sbx including ballmilled and shock-compacted TiNiSn0:95 Sb0:05 . The line is a linear ¢t to the data.73 (Reprinted from Ref. 73. Copyright 1999, American Institute of Physics.)

146

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SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

6.1. Tl9 GeTe6 Tl9 GeTe6 belongs to a large group of ternary compounds that may be thought of as derived from the isostructural compound Tl5 Te3 . There are no Te^Te bonds in the structure, and the Te nearest neighbors are Tl atoms. A simple crystal chemistry analysis indicates that tellurium is in the Te2 valence state, thallium is in the Tlþ state, and bismuth is in the Bi3þ valence state. The 4c crystallographic site is equally occupied with Tlþ and Bi3þ and octahedrally coordinated with Te atoms.75 This mixed valence site makes for a strong phonon scattering center, as shown in Fig. 23. This type of phonon scattering has been documented in Ru0:5 Pd0:5 Sb3 36;76 and Fe3 O4 ; 77 however, in this case the valence disorder is from two di¡erent atoms occupying the same crystallographic site, Tlþ and Bi3þ , and results in a very low thermal conductivity with L = 0.39 W/m-K at room temperature.75 These results strongly indicate how mixed valence results in a very low thermal conductivity and may be a useful phonon scattering mechanism in the search for new thermoelectric materials. The thermoelectric ¢gure of merit of Tl9 GeTe6 was estimated to exceed unity above 450 K. The very low thermal conductivity for this compound is the key for obtaining this ¢gure of merit.75 6.2. Tl2 GeTe5 and Tl2 SnTe5 The Tl^Sn^Te and Tl^Ge^Te systems both contain several ternary compounds, including a 2^1^5 composition in both systems.78 Both compounds are tetragonal and contain columns of Tl ions along the crystallographic c axis. Transverse to the c axis are alternate columns with chains of composition (Sn/Ge)Te5 . These compounds can be thought of as polytypes of one another, with di¡erent stacking sequences of (Ge/Sn)Te4 tetrahedra and TeTe4 square planar units linked into chains. Large ADP values con¢rm that a portion of the Tl atoms is loosely bound in these structures. Again, large ADP values are associated with low values of L , as previously discussed. The thermal conductivity is very low for both Tl2 SnTe5 and Tl2 GeTe5 . Apparently L in these polycrystalline samples is approximately 5 W/m-K at room temperature. This is less than one third of the value for pure Bi2 Te3 . At

κ tot

1

κ (W m

-1

-1 K )

4

κ lat

0.4

κe 0.1

κ min 4

10

40

T (K)

100

400

FIGURE 23. The total thermal conductivity (denoted tot Þ of Tl9 GeTe6 along with the calculated electrical, e , and phonon, lat , contributions. The ¢t to the data employs the expression AT0:93 + min , where A is a constant, T is the absolute temperature, and min is the minimum thermal conductivity, also plotted in the ¢gure.75 (Reprinted from Ref. 75. Copyright 2001, American Physical Society.)

Sec. 6

NOVEL CHALCOGENIDES AND OXIDES

147

room temperature the electronic contribution to was estimated to be about 20% for Tl2 SnTe5 but less than 10% for Tl2 GeTe5 , due to the higher resistivity.78 6.3. CsBi4 Te6 One of the more interesting new bulk materials that have recently been investigated for thermoelectric refrigeration is CsBi4 Te6 .79 This compound has a layered anisotropic structure composed of Bi4 Te6 layers alternating with layers of Csþ ions. The Csþ ions lie between the Bi4 Te6 layers and their atomic displacement parameters (ADPs) are almost twice as large as those of the Bi and Te atoms, indicating that Csþ may display dynamic disorder. This disorder, together with the complexity of the crystal structure, is presumably the cause of the relatively low thermal conductivity in this material. The thermal conductivity of dense polycrystalline pellets was measured to be 1.5 W/m-K at room temperature. 6.4. NaCo2 O4 Recently, dimensionless ¢gures of merit of 1.0 at 800‡K and 0.8 at 800‡C were reported for single-crystal and polycrystalline NaCo2 O4 , respectively,80;81 making this a promising high-temperature thermoelectric material, particularly since this is an oxide made up of light atoms with large electronegativity di¡erences, contradicting the general guidelines for good thermoelectric materials.82 NaCo2 O4 possesses a layered hexagonal structure that consists of two-dimensional triangular lattices of Co. The cobalt atoms are octahedrally surrounded by O atoms above and below each Co sheet. The resulting CoO2 layers are stacked along the hexagonal c-axis. Na atoms are in planes sandwiched by adjacent CoO2 -layers and randomly occupy 50% of the regular lattice sites in those planes. The material shows metallic-like transport properties as measured in single-crystal samples, with highly anisotropic behavior.80 Because of the low electrical resistivity and large thermopower, a large power factor of 50 W cm2 K2 at room temperature was reported in the in-plane direction.83 This power factor value exceeds that of Bi2 Te3 despite the much lower mobility estimated for NaCo2 O4 . Terasaki et al. suggested that strong electron^electron correlation in this layered oxide plays an important role in the unusually large thermopower observed.83 Another important characteristic of NaCo2 O4 is its low thermal conductivity. At room temperature, a total thermal conductivity of 2 W/m-K with lattice component of 1.8 W/m-K is reported for polycrystalline samples. Figure 24 shows the temperature dependence of L for polycrystalline (NaCa)Co2 O4 between 10 K and 300 K.84 For both samples in Fig. 24, L increases monotonically with increasing temperature. The solid curve A in the ¢gure is a Callaway model ¢t to the data, assuming only boundary, point-defect, and phonon^phonon umklapp scatterings are present, whereas the dashed curve B represent the calculated minimum thermal conductivity. Based on the ¢t, Takahata et al. conclude that these amorphous-like L are predominantly due to strong point-defect phonon scattering on the Na site between the Na atoms and the vacancies,84 even though the value of L (a ¢tting parameter which represents an inelastic scattering length) determined from the ¢t does not seem to have a clear physical origin. Recently, Rivadulla et al.85 reported a very di¡erent temperature dependence and room temperature value of L for polycrystalline NaCo2 O4 , compared to those in Fig. 24. The data are plotted in Fig. 25 and show typical temperature dependence

Chap. 1.5

SEMICONDUCTORS AND THERMOELECTRIC MATERIALS

Lattice Thermal Conductivity (mW/cm-K)

148

FIGURE 24. Lattice thermal conductivity of NaCo2 O4 . Open and closed circles represent data for samples no. 1 and no. 2, where the electron thermal conductivity was estimated from the Wiedemann^Franz law. Curve A is the calculation based on the Debye approximation, Curve B is the calculated minimum thermal conductivity, as discussed in Ref. 84. The inset shows data at 200 K.

for crystalline materials. A L peak is observed at 40 K, and at room temperature L 4.0 W/m-K, twice as large as that reported by Takahata et al.84 The origin of phonon scattering mechanisms that govern the thermal conductivity for this type of compound is an open question, the answer to which awaits further investigation. It is a prerequisite for assessing the thermoelectric properties of these materials.

10

1

0.1

0.01

11

10

100

Temperature (K) FIGURE 25. Lattice thermal conductivity of polycrystalline NaCo2 O4 .85

1000

Sec. 8

REFERENCES

149

7. SUMMARY We have reviewed thermal conductivities of conventional and newly developed thermoelectric materials. For most conventional materials and half-Heusler alloys, low lattice thermal conductivities are achieved via alloying between isomorphous compounds without deteriorating the electrical properties. In the cases of ¢lled skutterudites, clathrates, and some of the novel chalcogenides, guest ions can be inserted into the large interstitial voids of the crystal structures. These guest ions rattle inside the voids and therefore interact resonantly with low-frequency acoustic phonons, leading to signi¢cant thermal conductivity reduction. Phonon scattering by valence disorder is responsible for the low thermal conductivity observed in Tl9 GeTe6 . In-depth investigation on the NaCo2 O4 -based oxides, potential hightemperature thermoelectric materials, is much needed to clarify the exact phonon scattering mechanisms in these compounds. 8. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8.

9. 10. 11. 12. 13. 14. 15.

16. 17. 18.

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REFERENCES

151

45. D. T. Morelli, G. P. Meisner, B. Chen, S. Hu, and C. Uher Cerium Filling and Doping of Cobalt Triantimonide Phys. Rev. B 56, 7376^7383 (1997). 46. G. P. Meisner, D. T. Morelli, S. Hu, J. Yang, and C. Uher Structure and Lattice Thermal Conductivity of Fractionally Filled Skutterudites: Solid Solutions of Fully Filled and Un¢lled End Members Phys. Rev. Lett. 80, 3551^3554 (1998). 47. J. Yang, D. T. Morelli, G. P. Meisner, W. Chen, J. S. Dyck, and C. Uher E¡ect of Sn Substituting Sb on the Low Temperature Transport Properties of Ytterbium-Filled Skutterudites, Phys. Rev. B 67, 165207 (2003). 48. For two recent reviews see Chapter 6 of G. S. Nolas, J. Sharp, and H. J. Goldsmid, Thermoelectrics: Basics Principles and New Materials Developments (Springer-Verlag, New York, 2001), and G. S. Nolas, G. A. Slack, and S. B. Schujman Semiconductor Clathrates in Semiconductors and Semimetals, Vol. 69, edited by T. M. Tritt (Academic Press, San Diego, 2000), pp. 255^300, and references therein. 49. G. S. Nolas, J. L. Cohn, G. A. Slack, and S. B. Schujman Semiconducting Ge-Clathrates : Promising Candidates for Thermoelectric Applications Appl. Phys. Lett. 73, 178^180 (1998). 50. J. L. Cohn, G. S. Nolas, V. Fessatidis, T. H. Metcalf, and G. A. Slack Glass-like Heat Conduction in High-Mobility Crystalline Semiconductors Phys. Rev. Lett. 82, 779^782 (1999). 51. G. S. Nolas, T. J. R. Weakley, J. L. Cohn, and R. Sharma Structural Properties and Thermal Conductivity of Crystalline Ge-Clathrates Phys. Rev. B 61, 3845^3850 (2000). 52. V. Keppens, B. C. Sales, D. Mandrus, B. C. Chakoumakos, and C. Laermans When Does a Crystal Conduct Heat Like a Glass? Phil. Mag. Lett. 80, 807^812 (2000). 53. J. Dong and O. F. Sankey Theoretical Study of Two Expanded Phases of Crystalline Germanium: Clathrate-I and clathrate-II J. Phys. Condensed Matter 11, 6129^6145 (1999). 54. G. S. Nolas and C. A. Kendziora Raman Scattering Study of Ge and Sn Compounds with Type-I Clathrate Hydrate Crystal Structure Phys. Rev. B 62, 7157^7161 (2000). 55. J. Dong, O. F. Sankey, and C. W. Myles Theoretical Study of the Lattice Thermal Conductivity in Ge Framework Semiconductors Phys. Rev. Lett. 86, 2361^2364 (2001). 56. B. C. Chakoumakos, B. C. Sales, D. G. Mandrus, and G. S. Nolas Structural Disorder and Thermal Conductivity of the Semiconducting Clathrate Sr8 Ga16 Ge30 J. Alloys Comp. 296, 80^86 (1999). 57. J. Gryko, P. F. McMillan, R. F. Marzke, G. K. Ramachandran, D. Patton, S. K. Deb, and O. F. Sankey Low-Density Framework Form of Crystalline Silicon with a Wide Optical Band Gap Phys. Rev. B 62, R7707^7710 (2000) 58. G. B. Adams, M. O’Keeffe, A. A. Demkov, O. F. Sankey, and Y.-M. Huang Wide-Band-Gap Si in Open Fourfold-Coordinated Clathrate Structures Phys. Rev. B 49, 8048^8053 (1994). 59. G. S. Nolas, M. Beekman J. Gryko, G. Lamberton, T. M. Tritt, and P. F. McMillan Thermal Conductivity of the Elemental Crystalline Silicon Clathrate Si136 Appl. Phys. Lett. 82, 901^903 (2003). 60. W. Jeitschko Transition Metal Stannides with MgAgAs and MnCu2 Al-Type Structure Metall. Trans. 1, 3159, 1970. 61. R. V. Skolozdra, Y. V. Stadnyk, and E. E. Starodynova The Crystal Structure and Magnetic Properties of Me’Me’’Sn Compounds (Me’ = Ti, Zr, Hf, Nb; Me’’ = Co, Ni) Ukrain. Phys. J. 31, 1258^1261, 986. 62. F. G. Aliev, N. B. Brandt, V. V. Moshchalkov, V. V. Kozyrkov, R. V. Skolozdra, and A. I. Belogorokhov Gap at the Fermi Level in the Intermetallic Vacancy System RNiSn (R = Ti, Zr, Hf) Z. Phys. B 75, 167^171 (1989). 63. B. A. Cook, G. P. Meisner, J. Yang, and C. Uher High Temperature Thermoelectric Properties of MNiSn (M = Zr, Hf) Proc. 18th Intl. Conf. on Thermoelectrics (IEEE, Piscataway, NJ, 1999), pp. 64^67. 64. C. Uher, J. Yang, and G. P. Meisner Thermoelectric Properties of Bi-Doped Half-Heusler Alloys Proc. 18th Intl. Conf. on Thermoelectrics (IEEE, Piscataway, NJ, 1999), pp. 56^59. 65. C. Uher, J. Yang, S. Hu, D. T. Morelli, and G. P. Meisner Transport Properties of Pure and Doped MNiSn (M = Zr, Hf) Phys. Rev. B 59, 8615^8621 (1999). 66. H. Hohl, A. P. Ramirez, C. Goldmann, G. Ernst, B. Wolfing, and E. Bucher E⁄cient Dopants for ZrNiSn-Based Thermoelectric Materials J. Phys.: Condensed Matter 11, 1697^1709 (1999). 67. B. A. Cook and J. L. Harringa Electrical Properties of Some (1,1,1) Intermetallic Compounds J. Mat. Sci. 34, 323^327 (1999). 68. S. Bhattacharya, V. Ponnambalam, A. L. Pope, Y. Xia, S. J. Poon, R. T. Littleton IV, and T. M. Tritt E¡ect of Substitutional Doping on the Thermal Conductivity of Ti-based Half-Heusler Compounds Mat. Res. Soc. Symp. 626, Z5.2.1^z5.2.6 (2000).

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69. V. M. Browning, S. J. Poon, T. M. Tritt, A. L. Pope, S. Bhattacharya, P. Volkov, J. G. Song, V. Ponnambalam, and A. C. Ehrlich Thermoelectric Properties of the Half-Heusler Compound (Zr,Hf)(Ni,Pd)Sn Mat. Res. Soc. Symp. 545, 403^412 (1998). 70. Q. Shen, L. Chen, T. Goto, T. Hirai, J. Yang, G. P. Meisner, and C. Uher E¡ects of Partial Substitution of Ni by Pd on the Thermoelectric Properties of ZrNiSn-Based Half-Heusler Compounds Appl. Phys. Lett. 79, 4165^4167 (2001). 71. S. J. Poon Electronic and Thermoelectric Properties of Half-Heusler Alloys, in Semiconductors and Semimetals, Vol. 70, edited by T. M. Tritt (Academic Press, San Diego, CA, 2001), pp. 37^75. 72. J. W. Sharp, S. J. Poon, and H. J. Goldsmid Boundary Scattering and the Thermoelectric Figure of Merit Phys. Stat. Sol. (a) 187, 507^516 (2001). 73. T. M. Tritt, S. Bhattacharya, Y. Xia, V. Ponnambalam, S. J. Poon, and N. Thadhani E¡ects of Various Grain Structure and Sizes on the Thermal Conductivity of Ti-based Half-Heusler Alloys Proc. 20th Intl. Conf. on Thermoelectrics (IEEE, Piscataway, NJ, 2001), pp. 7^12. 74. S. Bhattacharya, Y. Xia, V. Ponnambalam, S. J. Poon, N. Thadhani, and T. M. Tritt Reductions in the Lattice Thermal Conductivity of Ball-Milled and Shock Compacted TiNiSn1 x Sbx HalfHeusler Alloys Mat. Res. Soc. Symp. 691, G7.1.1^G7.1.6 (1998). 75. B. Wolfing, C. Kloc, J. Teubner, and E. Boucher High Performance Thermoelectric Tl9 GeTe6 with an Extremely Low Thermal Conductivity Phys. Rev. Lett. 86, 4350^4353 (2001). 76. T. Caillat, J. Kulleck, A. Borshchevsky, and J. P. Fleurial Preparation and Thermoelectric Properties of Skutterudite-Related Phase Ru0:5 Pd0:5 Sb3 J. Appl. Phys. 79, 8419^8426 (1996). 77. G. A. Slack Thermal Conductivity of MgO, Al2 O3 , MgAl2 O4 and Fe3 O4 Crystals from 3 to 300 K Phys. Rev. 126, 427^441 (1962). 78. J. W. Sharp, B. C. Sales, D. G. Mandrus, and B. C. Chakoumakos Thermoelectric Properties of Tl2 GeTe5 and Tl2 SnTe5 Appl. Phys. Lett. 74, 3794^3797 (1999). 79. D. Y. Chung, T. Hogan, P. Brazis, M. Rocci-Lane, C. Kannewurf, M. Bastea, C. Uher, and M. G. Kanatzidis CsBi4 Te6 : A High-Performance Thermoelectric Material for Low-Temperature Applications Science 287, 1024^1027 (2000). 80. K. Fujita, T. Mochida, and K. Nakamura High-Temperature Thermoelectric Properties of NaCo2 O4 y Single Crystals Jpn. J. Appl. Phys., Part 1 40, 4644 (2001). 81. M. Ohtaki, Y. Nojiri, and E. Maeda Improved Thermoelectric Performance of Sintered NaCo2 O4 with Enhanced 2-Dimensional Microstructure Proc. 19th Intl. Conf. on Thermoelectrics (Babrow, Wales, 2000), pp. 190^195. 82. G.A. Slack New Materials and Performance Limits for Thermoelectric Cooling, in CRC Handbook of Thermoelectrics, edited by D. M. Rowe (CRC Press, Boca Raton, FL, 1995), pp. 407^440. 83. I. Terasaki, Y. Sasago, and K. Uchinokura Large Thermoelectric Power in NaCo2 O4 Single Crystals Phys. Rev. B 56, R12685^R12687 (1997). 84. K. Takahata, Y. Iguchi, D. Tanaka, T. Itoh, and I. Terasaki Low Thermal Conductivity of the Layered Oxides (NaCa)Co2 O4 : Another Example of a Phonon Glass and an Electron Crystal Phys. Rev. B 61, 12551^12555 (2000). 85. F. Rivadulla and J. B. Goodenough, unpublished.

Chapter 1.6

THERMAL CONDUCTIVITY OF SUPERLATTICES G. D. Mahan Department of Physics and Materials Research Laboratory Pennsylvania State University, University Park, PA, USA

1. INTRODUCTION The word superlattice describes a solid composed of alternate materials. Usually the materials are di¡erent semiconductors and are grown by molecular-beam epitaxy (MBE) or by chemical vapor deposition (CVD). Usually each material is a singlecrystalline semiconductor, and usually the superlattice is composed of alternate layers of two di¡erent materials. Usually the system is periodic, so material A has n layers, material B has m layers, and this pattern repeats. It is an advantage to have the lattice constants for each layer be the same within a fraction of a percent. Otherwise severe strains result near the interfaces. A typical superlattice has alternate layers of GaAs and AlAs and is represented as GaAs/AlAs. AlAs has a larger energy gap than GaAs, so conduction electrons are con¢ned to GaAs. These superlattices have been widely studied for their electrical properties. The investigation of their thermal properties is just beginning.1 8 Recently a number of superlattices have been grown to investigate their properties as thermoelectric devices.9 12 In some cases they have achieved a high ¢gure of merit.11 In thermoelectric applications it is desirable to have the thermal conductivity be as small as possible. For electronic applications one wants the thermal conductivity to be large in order to remove the Joule heat. We have repeatedly used the word ‘‘usually.’’ Superlattices do not have to be composed of only two materials, and the alternate layers do not need to be a periodic system. Indeed, for reducing the thermal conductivity along the growth axis (‘‘cross-plane’’ direction), it might be useful to intentionally introduce some disorder by making the layer thickness have a degree of randomness. Such random-

154

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ness would induce Anderson localization of the phonons.13 Also, the superlattices do not have to be composed of semiconductors. Some measurements have been done on metal^metal and metal^semiconductor superlattices. A superlattice is anisotropic, with a di¡erent thermal conductivity along the layers and in the cross-plane direction. It is useful to divide the topic into these two categories. The experiments and the theories for these two directions are very di¡erent. The experimental methods have been reviewed.1415 2. PARALLEL TO LAYERS The initial measurements and theories were for transport parallel to the layers. The simple viewpoint is that heat transport should be quite e⁄cient parallel to the layers. If the interfaces are atomically smooth, then phonons would specularly re£ect from these interfaces. Each layer becomes a phonon waveguide that e⁄ciently channels heat along each layer. Recent experiments on superlattices with atomically smooth surfaces con¢rms this expectation. The thermal conductivity parallel to the layers is similar to the bulk value. The initial measurements of thermal conductivity parallel to the layers found values smaller than bulk values by a factor of 4. Yao2 found in GaAs/AlAs superlattices that the thermal conductivity was similar to that of a random alloy of the two materials. This was explained in Ref. 16 as due to the interfaces boundaries not being perfectly planar. Atomic scale defects at the interface are e⁄cient scattering centers for the phonons. 3. PERPENDICULAR TO LAYERS The thermal conductivity of a superlattice along the growth axis is a complicated topic. The experiments are hard because the samples are quite small. Di¡erent groups, using di¡erent techniques, do not get the same results on the same sample. Generally, it is found that the thermal conductivity in the cross-plane direction is quite small. It is usually smaller than the thermal conductivity of the bulk materials in the layers, and it is smaller than a random alloy of the same materials. The theory has similar problems. Several theoretical issues are unresolved. The earliest theories found that the thermal conductivity of the superlattice was similar to the bulk material, and the interfaces had little e¡ect. This conclusion is now known to be wrong, and the earliest theories are now ignored.17 Before describing the di¡erent theoretical approaches, we discuss some major issues. 3.1. Thermal Boundary Resistance Thermal boundary resistance is also called Kapitza resistance. Kapitza found that when heat £owed between copper and super£uid helium, a temperature step developed at the interface that was proportional to the heat £ow: ð1Þ B T ¼ JQ : Heat £ow JQ has units of W/m2 , so the boundary conductance B has units of W/m2 -K. The boundary resistance RB ¼ 1=B has units of m2 K/W. The same

Sec. 3

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155

phenomena is now known to exist at every interface, even at a twin boundary of the same material. The boundary resistance has now been measured at a variety of interfaces.18;19 For twin boundaries it is quite low.20 It can be much larger for an interface between two di¡erent materials. Bartkowiak and Mahan noted that there are a whole range of interface transport parameters.21;22 Start with the equation for transport of electricity (JÞ and heat (JQ ) in a bulk thermoelectric, dV dT J ¼ þS ; ð2Þ dx dx JQ ¼ T S

dV dT K0 ; dx dx

JQ ¼ JST K

dT ; dx

K ¼ K 0 T S 2 ;

ð3Þ ð4Þ ð5Þ

where K 0 is the thermal conductivity at zero electric ¢eld, which is di¡erent than the thermal conductivity K at zero current. By analogy, similar equations for the boundary impedances are ð6Þ J ¼ B ðV þ SB T Þ; JQ ¼ B T SB V KB0 T ;

ð7Þ

JQ ¼ JSB T KB T ;

ð8Þ

KB ¼ KB0 B T SB2 :

ð9Þ

Here we have introduced the boundary impedances : SB (V/K) and KB (W/m2 K). The £ow of current has impedances if there is a temperature di¡erence T across the boundary, or if there is a potential di¡erence V , or both. The heat current behaves similarly. An Onsager relation proves that the same Seebeck coe⁄cient SB enters both terms. These equations are not the most general result. Stoner and Maris18 measured the Kapitza resistance between diamond and other crystals. Between diamond and lead the heat £ow was much higher than could be explained by a purely phonon conduction. Huberman and Overhauser23 suggested that phonons in diamond carried heat to the interface, and electrons in lead carried it away. A theory by Sergeev24 assumed that there was an abrupt change in temperature at the boundary between diamond and Pb. His theory agrees with experiment. If the superlattice carries heat by electrons and phonons, then the interface is a place of conversion between these two kinds of heat £ow. That would be an additional term in the preceding equations. The existence of a temperature step at a boundary is controversial. Many think that temperature di¡erences cannot be localized that rapidly. A temperature step was found in the ¢rst molecular dynamic simulation of heat £ow through a twin boundary in silicon,20 as shown in Fig.1. The theoretical system was a slab that was periodic in the xy plane and about 200 atoms thick in the z-direction. A low-index

156

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THERMAL CONDUCTIVITY OF SUPERLATTICES

FIGURE 1 Molecular dynamics simulation of heat £ow through a twin boundary in silicon. Vertical axis is temperature and horizontal axis is position in a slab. The temperature step is at the twin boundary. [From Maiti, Mahan and Pantelides, Sol. State Comm. 102, 517 (1997).]

twin boundary is in the middle of the slab. Heat was inserted on one side of the slab and removed from the other. This was the ¢rst calculation of Kapitza resistance that used purely numerical methods. The molecular dynamics simulation was entirely classical, so a classical de¢nition of temperature was used. The simulation calculated the position and velocity of each atom through millions of time steps. It is quite easy to de¢ne a classical temperature for each site : ~i Þ ¼ m hv2 i: kB T ð R ð10Þ 3 i The bracket h i denotes time averaging. There was a temperature step at the twin boundary. Since large heat £ows were used in the simulation, the temperature step was as large as 50 C. The calculation was done for several twin boundaries in silicon. A consistent value was found of B ¼ 0:7 GW-m2 /K. Recent calculations by Schelling et al.25 show similar results. Heat £ow in the cross-plane direction travels through a periodic array of interfaces. The thermal boundary resistance at each interface makes a large contribution to the thermal resistance of the device. This e¡ect is severe for superlattices with short periods. One theoretical problem is that the boundary resistance is unknown for most pairs of materials. 3.2. Multilayer Interference Most students learn about a multilayer interferometer in optics.26 A stack of glass plates that alternate between two di¡erent materials, each with a di¡erent refractive index, will ¢lter out most of the light. It is an interference e¡ect. The same phenomena of interference is found in superlattices. A typical superlattice also has alternate layers of two di¡erent materials. In this case the phonons in each layer have a di¡ferent sound velocity. That achieves the same kind of multilayer interference. However, the ¢ltering is e¡ective even for phonons of shorter wavelength. This feature was ¢rst discovered by Narayanamurti et al.1 They measured the transmission of high frequency phonons through a superlattice and showed that only phonons of selected frequencies could pass through. Phonons of a few frequencies carry very little heat, so the interference signi¢cantly reduces the thermal

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157

conductivity. Narayanamurti et al:1 showed the interference only for phonons going normal to the layers. There is a greater ¢ltering e¡ect for phonons going at oblique angles.27 It is important to evaluate all of the phonons in doing the calculation of heat transport in the superlattice. This interference is the primary reason that superlattices have a low value of thermal conductivity. The calculation of the thermal conductivity, including interference, was ¢rst done by Hyldgaard and Mahan27 for a Si/Ge superlattice, by Maris’s group,28 by Simkin and Mahan29 and by Bies et al:30 for a variety of superlattices. They found that the thermal conductivity in the cross-plane direction is typically a factor of 10 smaller than it is in either of the layer materials. This wave interference is not included in calculations using the Boltzmann equation, which is why earlier calculations failed to notice the e¡ect. One actually has to calculate all of the phonon modes of the superlattice. There are quite a few modes when the layers are thick. Simkin and Mahan noted that the phonon mean free path q was an important length. When qq >> 1, interference is important. When qq < 1, interference subsides, and Kapitza resistance at the interfaces was the primary phenomena. 3.3. What Is Temperature? The usual de¢nition of temperature is related to the average energy of a system of particles. This de¢nition is for a system in equilibrium and works even for nanoscale systems. However, our interest is in the transport of heat through nanoscale systems. Can temperature, which is an equilibrium concept, still be invoked in a nonequilibrium process such as heat £ow? The answer is a⁄rmative for macroscopic systems. They are so large that one can de¢ne a local temperature in each region in space. This local temperature will vary from region to region. Then one ~T . The question what ¢nds, for example, that the heat current is proportional to r is temperature? is really about the size of the regions over which a local temperature can be de¢ned. In many semiconductor superlattices, the layer thickness is 2^5 nm. Are these regions large enough to de¢ne a temperature? There have been several molecular dynamic simulations of heat £ow through a twin boundary in silicon.20;25;31 These simulations raise new problems which needed to be addressed. The most important problem is to de¢ne the temperature scale at ~i ðtn Þ and velocity di¡erent planes in the slab. The MD calculates the position R vi ðtn Þ at each time step in the simulation. It is relatively simple to store the velocities, and compute an averate kinetic energy over N steps in time by using Eq.(10). The time averaging must be done over very long times. Is the classical formula an adequate temperature scale? Another possible de¢nition of temperature is provided by quantum mechanics. The collective excitations of qÞ that depends the atomic motions are phonons. The phonons have a frequency ! ð~ upon the wave vector ~ q and polarization of the phonon. In quantum mechanics the average kinetic energy of the phonons is 1 1 X 2 mv2i ¼ h! ð~ qÞðiÞ2 h! ðqÞ=k T þ1 ; ð11Þ B i 1 2 4N ;~q e where N is the number of unit cells, which is also the number of ~ q points. The P polarization vectors are ðiÞ2 . They are normalized so that ðiÞ2 ¼ 3. In the limit h! ð~ qÞ, the Bose^Einstein occupation factors of high temperature, where kB T >>

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THERMAL CONDUCTIVITY OF SUPERLATTICES

are approximated as 2 kB T i þ12 : h! ð~ qÞ eh! ðqÞ=kB Ti 1

ð12Þ

In this high-temperature limit the quantum relation (Eq. 11) becomes identical to the classical one. (Eq. 10) The problem with many simulations is that they are not in the high-temperature limit. Silicon has optical phonons of very high energy (62 meV 750 K). For any temperature between 300 and 1000 K, the two de¢nitions of temperature [Eqs. (10)^(11)] gave very di¡erent values for Ti . What size of region is required to de¢ne a temperature? The classical de¢nition is entirely local, and one can de¢ne a temperature for each atom or plane of atoms. For the quantum de¢nition the length scale is de¢ned by the mean free path ‘~p of the phonon. If two regions of space have a di¡erent temperature, then they have a di¡erent distribution of phonons. The phonons can change their distribution by scattering. The most important scattering is the anharmonic process, where one phonon divides into two, or two combine to one. This process occurs on the length scale of the mean free path. A local region with a designated temperature must be larger than the phonon scattering distance. However, phonons of di¡erent frequency have very di¡erent values of ‘~p. Low-frequency phonons have a long ‘~p, and high-frequency phonons have a short ‘~p. For phonons which carry most of the heat, one can plausibly de¢ne an aveage mean free path. It is typically larger than the numerical slab used in the MC calculation. This case is called the Casimir limit, where the phonon mpf is larger than the size of the system. The phonon de¢nition of temperature requires that temperature not be de¢ned for a particular atom or a plane of atoms. There should be not abrupt variation in temperature between a plane of atoms. Although this de¢nition seems quite reasonable, it makes the numerical results in Fig. 1 quite puzzling. The numerical simulation by di¡erent groups do show an abrupt change in the kinetic energy of a plane of atoms at the twin boundary. Regardless of which temperature scale is adopted10 , or11 , a graph of temperature versus distance will show an abrupt change. A possible resolution for this puzzle is that a grain or twin boundary may form a natural boundary for a region of temperature. The statement that temperature cannot be de¢ned within a scale of distance given by ‘~p may not apply across grain boundaries. Even if one adopts this hypothesis, it still means that temperature cannot vary within a grain, or within a superlattice layer, on a scale smaller than ‘~p. If the layer thickness of the superlattice is less than ‘~p, then the whole layer is probably at the same temperature. This point is emphasized, since all theories of heat transport in superlattices have assumed that one could de¢ne a local temperature T ðzÞ within each layer. This theoretical treatment is wrong for superlattices with short periods. Although the discussion of temperature has been cast in the framework of MD simulations, the issues are more general. One of the major issues of thermal transport in nanoscale systems is whether temperature can be de¢ned locally. If it cannot, then how is transport calculated ? Another approach is to adopt a Landauer formalism, assume there are two thermal reservoirs at known temperatures, and consider the ballistic £ow of heat between them. This does not work for nanoscale devices since the values of ‘~p are much smaller than the distance between the reservoirs. Hence, heat £ow is di¡usive

Sec. 3

PERPENDICULAR TO LAYERS

159

rather than ballistic. How do you calculate di¡usive heat £ow without a local temperature? The theory of thermal conductivity is simple if the system satis¢es two conditions: (1) the layers are thick enough that one can ignore interference, and (2) the layers are thin enough that each layer is at the same temperature. In that case assume the system has n interfaces. Consider the heat £ow at any interface between two materials 1 and 2. The heat £ow from 1 to 2 is 12 T1 . The heat £ow from 2 to 1 is 21 T2 . The principle of detailed balance requires that 12 ¼ 21 . If two layers were at the same temperature and 12 6¼ 21 , then the layers would not exchange the same amount of heat. One layer would heat up, the other would cool down, which violates the second law of thermodynamics. So 12 ¼ 21 B . Then the net heat £ow in that one interface is B ðT1 T2 Þ. One can extend this argument to n-interfaces and ¢nd that the net heat £ow is B JQ ¼ ðTH TC Þ: ð13Þ n The same reasoning can be applied at any temperature. At low temperatures the heat £ow at one interface goes as fðT1 Þ fðT2 Þ ¼ 0 ðT14 T24 Þ. The T 4 law for phonons is the same as for photons. In that case the same reasoning gives 0 JQ ¼ ðTH4 TC4 Þ: ð14Þ n The general result, valid at any temperature in a superlatttice of alternate materials, is 1 JQ ¼ ½fðTH Þ fðTC Þ; ð15Þ n where fðT Þ is the general function that goes as T 4 at low temperatures and as T at high temperatures. For thicker superlattices one is tempted to modify this formula with the thermal resistance of the bulk of the layers, resulting in TH TC JQ ¼ ; ð16Þ n=B þ L1 =K1 þ L2 =K2 where Ki and Li are the thermal conductivity and total thickness of the two materials. 3.4. Superlattices with Thick Layers Superlattices with thick layers are an important subtopic. In these cases one can ignore wave interference and treat the boundary e¡ects, using Boltzmann equations for electrons and phonons. Kapitza resistance is the primary phenomenon. Nevertheless, the topic has interesting features. In thermoelectric devices it is important to have a £ow of electric current and heat. Both electrons and phonons go through the interface, and both have boundary resistances.22 They di¡er. In this case the foregoing treatment for the phonon part of the thermal conductivity of a superlattice is wrong, since the electrons and phonons invariably exchange energy. This exchange is not due to phonon drag, but is an interface phenomenon. Most of the calculations have been done with a formulism pioneered in Russia.3234 They assume each layer has di¡erent temperature for electrons Te ðzÞ and phonons Tp ðzÞ. They become di¡erent since electrons and phonons have dif-

160

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THERMAL CONDUCTIVITY OF SUPERLATTICES

FIGURE 2 Temperatures of electrons (solid curve) and phonons (dashed curve) for heat £ow in the cross-plane direction in a superlattice composed of Bi2 Te3 /Sb2 Te3 . Vertical scale is temperature, horizontal axis is position in microns. Calculations by Bartkowiak and Mahan.21;22

ferent boundary resistances and di¡erent values of T at each interface. There is a healing length over which the two interacting systems (electrons and phonons) return to local equilibrium. The healing lengths are many nanometers. In a superlattice with layer thicknesses of a few nanometers, the electron and phonon temperatures are totally di¡erent in each layer. These calculations predict some wierd behavior. A typical result is shown in Fig. 2 from Bartkowiak and Mahan.21;22 Actual results depend on the boundary resistances, for which we used theoretical estimates. Whether these predicted e¡ects are real depends on whether our estimates are correct and whether the temperature can be de¢ned on a local length scale. The coupled equations for the heat exchange between electrons and phonons22;33 are Ke

d2 T e ¼ J 2 P T ; dx2

ð17Þ

d2 T p ¼ P T ; dx2

ð18Þ

Kp

T ¼ Te Tp ;

ð19Þ

where Ke;p are the bulk thermal conductivity of electrons and phonons. Joule heating ðJ 2 Þ generates electronic heat in the layer. The terms P T exchange heat between the electron and phonon systems. The constant P is well known for metals,35 and we have calculated it for semiconductors. The length scale ðÞ over which the electron and phonon systems come to the same temperature is given by Ke Kp 2 ¼ : ð20Þ P ðKe þ Kp Þ Since P depends on the density of conduction electrons, each material will have a di¡erent length. The scale of is many nanometers. Short-period superlattices may never have the electron and phonon temperatures in agreement at any point.

Sec. 4

‘‘NON-KAPITZIC’’ HEAT FLOW

161

4. ‘‘NON-KAPITZIC’’ HEAT FLOW A measurement of electrical resistance always uses four probes on the sample. Soldering a wire onto the sample causes ‘‘non-Ohmic’’ contacts, so the voltage change must be measured with separate wire leads. Until recently, similar measurements on thermal conductance used only two contacts. The interface did not cause nonlinear behavior analogous to non-Ohmic electrical contacts. Recently there has been an appreciation of the Kapitza resistance at the interface. However, it is included by assuming a linear behavior. The Kaptiza resistance is another thermal resistance in series with that of the sample. Here we wish to discuss the possibility that there may be nonlinear behavior in the heat £ow at interfaces, which cannot be described simply by a boundary resistance. This nonlinear heat £ow is analogous to the non-Ohmic electrical contacts. We have been searching for a name for this process. I propose we name surface resistance after Kapitza (Kz=m2 -K/W) and call this behavior ‘‘non-Kapitzic.’’ It is likely that non-Kapitzic heat £ow has been present in all measurements of heat £ow. However, it has been on a length scale too small to be observed. Nonlinear e¡ects are on the nanoscale. They should play a role in the measurement and theory of heat transport in nanoscale devices. There have been numerous MD calculations of heat transport in one-dimensional lattices.3643 A chain of atoms connected only by harmonic springs will have heat conduction only by ballistic pulses. Some mechanism of scattering the phonons is required for heat di¡usion. Usually that is included by a nonlinearity in the springs or by the addition of impurities or isotope scattering. The usual procedure has been to introduce some anharmonic component into the spring constant, such as a bit of quartic potential energy. Nearly all of these calculations fail to ¢nd ordinary di¡usion of heat. The heat £ow fails to have the right scaling with the number of atoms in the chain ðJQ / 1=NÞ;29;4042 and the temperature along the chain is not linear. An example from my own group,29 is shown in Fig. 3. This phenomenon is explained in Ref.(43) as due to non-Kapitzic e¡ects. The results are all based on how one puts in the heat at one end of the chain and takes it out on the other side. The usual method, due to Hoover,44 used by us20 and

FIGURE 3 One-dimensional heat £ow as a function of chain length N for harmonic and anharmonic lattices. The same temperature is at the ends. The nonlinear chain does not scale as 1=N. Calculations by Simkin and Mahan (unpublished).

162

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THERMAL CONDUCTIVITY OF SUPERLATTICES

nearly everyone, causes nonequilibrium e¡ects to persist far into the interior of the chain. The earlier studies did not have chains long enough to get the interior of the chain away from the surface e¡ects. The message from these very di¡erent numerical studies is that surface e¡ects persist far into the chain. Even very anharmonic lattices take a long distance to relax into the di¡usive regime, which has a temperature which varies linearly with distance. In the surface region the distribution of phonons cannot be described by a single parameter such as temperature. Since many simulations, including ours, show similar behavior, it seems to be a universal phenomenon. Do experimental systems show the same non-Kapitzic behavior? No one knows. Answering this question is a future task for experimentalists. 4.1. Analytic Theory Most theories of transport in solids employ the Boltzmann equation (BE). For both electron and phonon transport, the form of the equation, and the form of the various scattering mechanisms are very well known. This theory can explain, in bulk homogeneous materials, the dependence of the electrical conductivity, the thermal conductivity, and the Seebeck coe⁄cient on temperature, impurity content, isotope scattering, and quantum con¢nement. There have been several calculations of thermal conductivity of the superlattice which have solved the Boltzmann equation. That of Ren and Dow16 did not predict a large reduction of thermal conductivity and disagreed with experiments. Several calculations from Chen’s group45;46 agree much better with experiment. However, the Boltzmann equation treats electrons and phonons as classical particles. One is solving, say for phonons, for the density fðr; ! ðqÞ; tÞ of excitations qÞ at point r at time t. The with polarization , wave vector q, and frequency ! ð~ wave nature of the excitation is neglected, as is any interference phenomena caused by the wave nature of the phonons. Furthermore, the scattering rates in the BE are calculated under the assumption that the system is only slightly perturbed from equilibrium. The solutions to the BE assume the existence of a local temperature. Neither of these two assumptions may be valid in nanoscale devices. Wave interference becomes important in nanoscale devices. The wavelengths of the phonons are similar to the length scale of the microstructure. At room temperature, in most solids, all of the phonon states in the Brillouin zone are involved in the transport. Their wavelengths span the range from atomic dimensions to the size of the sample. One method is to calculate the phonon states for the actual microstructure, including interference, and use those states in the BE. For transport in a superlattice, this approach puts in some of the wave phenomena. The phonon states depend signi¢cantly on the interference due to scattering from the multiple-layer boundaries of the superlattice. Solving this problem by using the BE is also complicated by phonon band folding. There are many superlattice bands, phonons scatter between them, and the BE becomes a matrix equation of large dimension. This calculation is quite ambitious and has never been done. Even doing it does not include all wave interference phenomena. Another possibility is to use the quantum Boltzmann equation47 to solve for the ~; t; !; qÞ. Compared to the BE there is one more vector variable in distribution fðR the argument that makes the solutions more complex. This more fundamental

Sec. 5

SUMMARY

163

equation does include wave information. However, it is di⁄cult to solve and is seldom used. There have been many calculations of thermal conductivity in the cross-plane direction. Most are based on the standard formula for thermal conductivity X Z d3 q dnB ð! ð~ qÞÞ 2 K ¼ h vz ðqÞ ! ð~ qÞ ð~ qÞ ; ð21Þ dT ð2Þ3 qÞÞ is the where vz ðqÞ is the velocity of the phonon, ðqÞ is the lifetime, and nB ð! ð~ Boson occupation function. This formula is derived from the BE. Calculations by Kato et al:;48 Hyldgaard and Mahan,27 Tamura et al:,28 Simkin and Mahan,29 Bies et al:;30 and Kiselev et al:49 just include Eq.(21) the actual phonon modes of the superlattice and evaluate. Usually, the lifetime ðqÞ or the mean free path ‘~p is selected to be the same as in the homogeneous material. These calculations show that thermal conductivity in the superlattice is reduced signi¢cantly, sometimes by a factor of 10, compared to that of the constituents of the superlattice. This large reduction agrees with experimental ¢ndings. Simkin and Mahan29 used a complex wave vector to compute the superlattice modes. The imaginary part of the wave vector was a phenomenological way of including the mean free path in the calculation of the phonon modes. This calculation showed a minimum in the thermal conductivity as a function of superlattice period. Most alternate theories are purely numerical. Molecular dynamics (MD) is far more suitable for a phonon system than for an electron system. The phonon modes can be calculated quite accurately with classical methods. Quantum e¡ects are important at low temperatures but relatively unimportant in most solids for phonon e¡ects at room temperature or above. Wave e¡ects are included automatically. Using an anharmonic potential between neighboring atoms includes e¡ects such as one phonon dividing in two, or two phonons combining into one. One limitation on MD is that it is limited to insulators. In order to model an actual nanoscale device, thousands of atoms have to be included in the simulation. This calculation is beginning to be practical with modern parallel computers. 5. SUMMARY The calculation of the thermal conductivity of a superlattice is rather easy in some cases. If the layers are thick and all of the heat is carried by phonons, then one can use Kapitza resistances at interfaces and Boltzmann equations for the interior of the layers. These calculations are rather easy and predict that the main in£uence of the superlattice is the thermal boundary resistance at the interfaces. There is much interest in superlattices where the layers have a thickness of a few nanometers. In this case calculating thermal conductivity runs into di⁄culties. One has to include (i) wave interference and (ii) nonlocal temperature scales. Further complications arise if a signi¢cant amount of heat is carried by electrons. The electrons and phonons exchange heat at the interface and in the interior of the layers. They have di¡erent boundary resistances. The electrons and phonon systems are not in equilibrium with each other throughout the superlattice. MD cannot accurately describe the transport by electrons, nor can it describe the exchange of energy between the phonon and electron systems. If one throws out the concept of a local temperature, so the BE cannot be used,

164

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THERMAL CONDUCTIVITY OF SUPERLATTICES

then there is no known way to solve for the heat transport and thermal conductivity. Many semiconductor devices depend on the electric currents provided by the electrons. The heat currents have components from both electrons and phonons. Presently there is no accurate way to model the heat £ows in these nanoscale systems while including the exchange of heat between electrons and phonons. A major theoretical challenge is to invent a new method of solving this and related transport problems. 6. REFERENCES 1. 2. 3. 4. 5. 6.

7.

8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20.

21. 22.

V. Narayanamurti, H. L. Sto«rmer, M. A. Chin, A. C. Gossard, and W. Wiegmann Selective Transmission of High-Frequency Phonons by a Superlattice Phys. Rev. Lett. 43, 2012^2016 (1979). T. Yao Thermal Properties of AlAs/GaAs Superlattices Appl. Phys. Lett. 51, 1798 (1987). X. Y. Yu, G. Chen, A. Verma, and J. S. Smith Temperature Dependence of Thermophysical Properties of GaAs/AlAs Periodic Structure Appl. Phys. Lett. 67, 3554^6 (1995). W. S. Capinski and H. J. Maris Thermal Conductivity of GaAs/AlAs Superlattices Physic B 219 220, 699^701 (1996). S. M. Lee, D. G. Cahill, and R. Venkatasubramanian Thermal Conductivity of Si-Ge Superlattices Appl. Phys. Lett. 70, 2957^2959 (1997). W. S. Capinshki, H. J. Maris, T. Ruf, M. Cardona, K. Ploog, and D. S. Katzer ThermalConductivity Measurements of GaAs/AlAs Superlattices Using Picosecond Optical Pump-and-Probe Technique Phys. Rev. B 59, 8105^8113 (1999). S. T. Huxable, A. R. Abramson, C. L. Tien, A. Majumdar, C. LaBounty, X. Fan, G. H. Zeng, J. E. Bowers, A. Shakouri, and E. T. Croke Thermal Conductivity of Si/SiGe and SiGe/SiGe Superlattices Appl. Phys. Lett. 80, 1737^1739 (2002). B. Yang, J. L. Liu, K. L. Wang and G. Chen Simultaneous Measurements of Seebeck Coe⁄cient and Thermal Conductivity across Superlattices Appl. Phys. Lett. 80, 1758^1760 (2002). G. D. Mahan and H. B. Lyon Thermoelectric Devices Using Semiconductor Quantum Wells J. Appl. Phys. 76, 1899^1901 (1994). J. O. Sofo and G. D. Mahan Thermoelectric Figure of Merit of Superlattices Appl. Phys. Lett. 63, 2690 (1994). R. Venkatasubramanian, E. Sivola, T. Colpitts, and B. O’Quinn Thin-Film Thermoelectric Devices with High Room-Temperature Figures of Merit Nature 413, 597 (2001). G. Chen and A. Shakouri Heat Transfer in Nanostructures for Solid-State Energy Conversion J. Heat Transfer 124 (2), 242^252 (2002). M. J. McKenna, R. L. Stanley, and J. D. Maynard E¡ects of Nonlinearity on Anderson Localization Phys. Rev. Lett. 69, 1807^1810 (1992). D. G. Cahill, K. Goodson, and A. Majumdar Thermometry and Thermal Transport in Micro/ Nanoscale Solid State Devices and Structures J. Heat Transfer 124 (2), 223^241 (2002). D. G. Cahill, W. K. Ford, K. E. Goodson, G. D. Mahan, A. Majumdar, H. J. Maris, R. Merlin, and S. R. Phillpot Nanoscale Thermal Transport J. Appl. Phys. 93, 793^818 (2003). P. Hyldgaard and G. D. Mahan Phonon Knudsen Flow in GaAs/AlAs Superlattices, Thermal Conductivity 23, 171^182 (1996). S. Y. Ren and J. D. Dow Thermal Conductivity of Superlattices Phys. Rev. B 25, 3750^3755 (1982). R. J. Stoner and H. J. Maris Kapitza Conductance and Heat Flow between Solids at Temperatures from 50 to 300 K Phys. Rev. B 48, 16373^16387 (1993). D. G. Cahill, A. Bullen and S. M. Lee Interface Thermal Conductance and the Thermal Conductivity of Multilayer Thin Films High Temp.^High Pressure 32, 135^142 (2000). A. Maiti, G. D. Mahan, and S. T. Pantelides Dynamical Simulations of Nonequilibrium Processes^ Heat Flow and the Kapitza Resistance Across Grain Boundaries Sol. State. Comm. 102, 517^521 (1997). G. D. Mahan and M. Bartkowiak Wiedemann^Franz Law at Boundaries Appl. Phys. Lett., 74, 953^954 (1999). M. Bartkowiak and G. D. Mahan Heat and Electricity Transport Through Interfaces, Semiconductors and Semimetals Vol. 71 (Academic Press, 2001), pp. 245^273.

Sec. 6

REFERENCES

165

23. M. L. Huberman and A. W. Overhauser Electronic Kapitza Conductance at Diamond-Pb Interface Phys. Rev. B 50, 2865 (1994). 24. A. V. Sergeev Electronic Kapitza Conductance due to Inelastic Electron-Boundary Scattering Phys. Rev. B 58, R10199 (1998). 25. P. K. Schelling, S. R. Phillpot, and P. Keblinski Comparison of Atomic-level Simulation Methods for Computing Thermal Conductivity Phys. Rev. B 65(14), 4306 (2002). 26. P. Hariharan Optical Interferometry (Academic, Sydney, 1985). 27. P. Hyldgaard and G. D. Mahan Phonon Superlattice Transport Phys. Rev. B 56, 10754^10757 (1997). 28. S. I. Tamura, Y. Tanaka, and H. J. Maris Phonon Group Velocity and Thermal Conductivity in Superlattices Phys. Rev. B 60, 2627^2630 (1999). 29. M. V. Simkin and G. D. Mahan Minimum Thermal Conductivity of Superlattices Phys. Rev. Lett. 84, 927^930 (2000). 30. W. E. Bies, H. Ehrenreich, and E. Runge, Thermal Conductivity in HgTe/CdTe Superlattices J. Appl. Phys. 91, 2033^2036 (2002). 31. A. R. Abramson, C. L. Tien, and A. Majumdar Interface and Strain E¡ects on the Thermal Conductivity of Heterostructures J. Heat Transfer 124 (5), 963^970 (2002). 32. L. P. Bulat and V. G. Yatsyuk Theory of Heat Conduction in Solids Sov. Phys. Solid State 24, 1994^1995 (1982). 33. L. P. Bulat and V. G. Yatsyuk Thermal E¡ects at Boundaries of Solids Sov. Phys. Semicond. 18, 383^384 (1984). 34. L. I. Anatychuk, L. P. Bulat, D. D. Nikirsa, and V. G. Yatsyuk In£uence of Size E¡ects on the Properties of Cooling Thermoelements Sov. Phys. Semicond. 21, 206^207 (1986). 35. P. B. Allen Theory of Thermal Relaxation of Electrons in Metals Phys. Rev. Lett. 59, 1460^1463 (1987). 36. R. Bourbonnais and R. Maynard Energy Transport in One- and Two-Dimensional Anharmonic Lattices with Isotropic Disorder Phys. Rev. Lett. 64, 1397^1400 (1990). 37. S. Wang Localized Vibrational Modes in an Anharmonic Chain Phys. Lett. A 182, 105^108 (1993). 38. S. Wang In£uence of Cubic Anharmonicity on High Frequency Modes Phys. Lett. A 200, 103^108 (1995). 39. S. Sen, R. S. Sinkovits, and S. Chakravarti Algebraic Relaxation Laws for Classical Particles in 1D Anharmonic Potentials Phys. Rev. Lett. 17, 4855^4859 (1996). 40. S. Lepri, R. Livi, and A. Politi Heat Conduction in Chains of Nonlinear Ascillators Phys. Rev. Lett. 78, 1896^1899 (1997). 41. S. Lepri, R. Livi, and A. Politi On the Anomalous Thermal Conductivity of One-Dimensional Lattices Europhy. Lett. 43, 271^276 (1998). 42. C. Giardina, R. Livi, A. Politi, and M. Vassalli Finite Thermal Conductivity in 1D Lattices Phys. Rev. Lett. 84, 2144^2147 (2000). 43. O. Gendelman and A.V. Savin Normal Heat Conductivity of the One-Dimensional Lattice with Periodic Potential of Nearest Neighbor Interaction Phys. Rev. Lett. 84, 2381 (2000). 44. W. G. Hoover Canonical Dynamics: Equilibrium Phase-Space Distributions Phys. Rev. A 31, 1693^ 1697 (1985). 45. G. Chen Size and Interface E¡ects on Thermal Conductivity of Superlattices and Periodic Thin Film Structures J. Heat Transfer, 119, 220^229 (1997). 46. G. Chen and M. Neagu Thermal Conductivity and Heat Transfer in Superlattices Appl. Phys. Lett. 71, 2761^2763 (1997). 47. G. D. Mahan Many-Particle Physics 3rd ed. (Kluwer-Plenum, 2000). 48. H. Kato, S. Tamura, and H. J. Maris Resonant-Mode Conversion and Transmission of Phonons in Superlattices Phys. Rev. B 53, 7884^7889 (1996). 49. A. A. Kiselev, K. W. Kim, and M. A. Stroscio Thermal Conductivity of Si/Ge Superlattices: A Realistic Model with a Diatomic Unit Cell Phys. Rev. B 62, 6896^6899 (2000).

Chapter 1.7

EXPERIMENTAL STUDIES ON THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES Bao Yang Department of Mechanical Engineering University of Maryland College Park, MD, USA

Gang Chen Department of Mechanical Engineering Massachusetts Institute of Technology Cambridge, MA, USA

1. INTRODUCTION The thermal conductivity of thin ¢lms is a very important parameter for a wide range of applications, such as microelectronic devices, photonic devices, thermoelectric devices, and optical and thermal barrier coatings.1 4 Experimental studies on the thermal conductivity of thin ¢lms can be traced back to the mid-1960s when size dependence of the thermal conductivity in metal ¢lms was ¢rst reported.5;6 Since the 1980s, the thermal properties of thin ¢lms have drawn increasing attention, due to the demands of thermal management in the rapidly growing microelectronics and optoelectronics industries1 4;7 9 and to the resurgence of thermoelectrics in the early 1990s.4;10 12 In microelectronics, integrated circuits (ICs) employ various insulating, semiconducting, and metallic thin ¢lms. Because the power density and speed of ICs keep increasing, thermal management becomes more challenging, and the thermal conductivity of the constituent thin ¢lms becomes more important for the device design. Semiconductor lasers, often made of

168 Chap. 1.7

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

heterostructures to control electron and photon transport, encounter more severe thermal management problems because they are more sensitive to temperature. The maximum optical output power of these semiconductor lasers depends signi¢cantly on the operating temperature, and the lasing wavelength shifts with temperature £uctuation. The thin ¢lms used in microelectronic and photonic devices need to have high thermal conductivity in order to dissipate heat as e⁄ciently as possible. On the other hand, thermoelectric devices call for materials or structures with low thermal conductivity because the performance of thermoelectric devices is determined by the ¢gure of merit Z=S 2 /k, where k is thermal conductivity, is electrical conductivity, and S is the Seebeck coe⁄cient.13 Nanostructured materials, such as superlattices, can have drastically reduced thermal conductivity in comparison to the corresponding bulk values, and thus have become promising candidates in the search for high-e⁄ciency thermoelectric materials.10 12;14 Other applications calling for thin ¢lms with low thermal conductivity are high-temperature coatings for engines. The increasing interest in thermal conductivity of thin ¢lms and superlattices is coincident with advances in microfabrication technology and measurement techniques. Measurements of the thermal conductivity of thin ¢lms and superlattices have proven very challenging, and the conventional methods for bulk materials may not apply to these thin ¢lms. New measurement techniques for thin-¢lm thermophysical properties have been reported. Among these methods, the 3! method,15;16 developed by Cahill et al: in late 1980s, may be the most commonly used technique for measuring thermal conductivity in the direction perpendicular to thin ¢lms. This method was later extended to measure the thermal conductivity in the perpendicular and parallel directions simultaneously.17 Other microfabrication-based methods have also been developed. The optical pump^probe method18 and optical calorimetry method19 are also widely used. Chapter 2.2 reviews experimental techniques for the measurement of thermal conductivity in thin ¢lms. The size e¡ects on thermal conductivity become extremely important when the ¢lm thickness shrinks to be comparable to the mean free path or wavelength of the heat carriers (i.e., phonons in semiconducting and dielectric materials and electrons in metals).20 25 Scattering at boundaries and interfaces imposes additional resistance to thermal transport and reduces the thermal conductivity of thin ¢lms. When the ¢lm thickness is comparable to the wavelength of heat carriers, the quantum size e¡ects step in. As a consequence, the fundamental properties, such as velocity and density of states of heat carriers, will be modi¢ed, which may contribute to the reduction in thermal conductivity in thin ¢lms. Furthermore, microstructure and stoichiometry in thin ¢lms and superlattices strongly depend on the ¢lm growth process, and any variations in structure and stoichiometry may signi¢cantly in£uence the thermal conductivity.1;2 The complexity of structures, stoichiometry, and scattering on interfaces, boundaries, and imperfection in thin ¢lms yield many degrees of freedom that challenge the understanding and modeling of thermophysical properties of thin ¢lms. The existing models for thermal transport in thin ¢lms and superlattices are still not totally satisfactory. Chapter 1.5 reviews the modeling of thermal transport in thin ¢lms and superlattices. In this review we will summarize some experimental results on the thermal conductivity of thin ¢lms and superlattices. We start with a brief review of thermal conductivity in metallic thin ¢lms. The thermal conductivity of dielectric, semiconducting, and semimetal thin ¢lms will be discussed next. Emphasis will be on those

Sec. 2

THERMAL CONDUCTIVITY OF METALLIC THIN FILMS

169

thin ¢lms with applications in microelectronics and thermoelectrics. Thermal transport in semiconductor superlattices will be reviewed at the end of the chapter. 2. THERMAL CONDUCTIVITY OF METALLIC THIN FILMS Metallic thin ¢lms are widely used in microelectronics and micromachined sensors and actuators.26 30 Thermal transport in metal thin ¢lms has been studied since the 1960s because the kinetics of growth and electromigration in metal thin ¢lms is related to their thermal properties. In the 1960s the thickness-dependent thermal conductivity, along the ¢lm-plane direction (the in-plane direction), was observed at low temperatures in Al foils by Amundsen and Olsen,5 and in Ag ¢lms by Abrosimov et al.6 In the 1970s, Chopra and co-workers did a series of experiments on the temperature dependence and ¢lm thickness dependence of the in-plane thermal conductivity in Cu thin ¢lms.26;27;31 In their work a steady-state method was employed for the measurements at high temperatures, whereas a transient method was used for low-temperature measurements. Later experiments by Wachter and Volklein considered radiation loss in thin metal ¢lms, so thermal conductivity and emissivity could be determined.32 In this section Cu thin ¢lms are used as an example for thermal transport in metallic ¢lms. Copper thin ¢lms are important in modern CMOS technology, replacing Al thin ¢lms to reduce the RC delay in interconnect networks. In metals the heat conduction is dominated by electrons, but the contribution from phonons is very small. Electron scattering at boundaries of thin ¢lms may impose additional resistance on the electron transport, and thus size e¡ects on thermal conductivity can be observed. Figure 1 shows the dependence of the inplane thermal conductivity on ¢lm thickness for two di¡erent temperatures, 100 K and 325 K, along with the thermal conductivity of bulk Cu.26;27;31 The thermal conductivity of thin ¢lms is reduced in comparison to their bulk values, and ther-

FIGURE 1 Dependence of the in-plane thermal conductivity on ¢lm thickness for Cu thin ¢lms deposited on a mica slice [data from refs 26, 27, and 31].

170 Chap. 1.7

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

ThermalConductivity(W/m-K)

mal conductivity is a strong function of ¢lm thickness below a certain thickness value, above which it almost remains constant. The thickness-dependent region is smaller for 325 K than that for 100 K, and enhanced size e¡ects are observed at lower temperatures as expected. Fuchs theory,33 which considers the surface scattering of electrons by solving the Boltzmann transport equation, is often employed to explain the size dependence of thermal conductivity in metal thin ¢lms. Fuchs theory can reasonably explain the data for thicker ¢lms, but the discrepancy between the prediction and the data for thinner ¢lms is relatively large, because Fuchs theory considers only surface scattering and neglects grain boundary scattering. Very thin ¢lms typically have smaller grains and thus more grain boundary scattering. Models that consider grain boundary scattering lead to much better agreement with experimental results.34 The thermal conductivity of metal thin ¢lms also shows a di¡erent temperature dependence than the bulk form. As seen in Fig. 2, the trend for thicker Cu ¢lms is similar to bulk Cu; i.e., the thermal conductivity decreases with increasing temperature because, at high temperatures, electron-phonon scattering becomes stronger. As ¢lm thickness decreases, however, the temperature dependence of thermal conductivity also decreases, and ultimately a reversal of the temperature dependence emerges for ¢lms thinner than 400 A. This reversal can be attributed to boundary or grain boundary scattering, which is more important as the ¢lm thickness goes down and ultimately outplays the electron-phonon scattering in very thin ¢lms. Because boundary scattering and Fermi velocity are relatively independent of temperature, thermal conductivity roughly follows the temperature dependence of the electron speci¢c heat. Interestingly in the data by Chopra and Nath,26 the electrical resistivity, contrary to thermal conductivity, always increases with increasing temperature, no matter how thin the ¢lm is. The authors suggested that the Lorenz number could not remain constant anymore and should be a function of temperature and ¢lm thickness, because the electron scattering at the boundaries has di¡erent e¡ects on the energy transport for thermal conductivity and momentum transport for electrical 500 Bulk Film,3000Å Film,1200Å

400

Film,400Å Film,100Å

300 200 100 0 100

200

300

400

500

Temperature(K) FIGURE 2 Temperature dependence of the in-plane thermal conductivity of Cu thin ¢lms with di¡erent ¢lm thickness [data from Refs. 26, 27, and 31].

Sec. 3

THERMAL CONDUCTIVITY OF DIELECTRIC FILMS

171

conductivity. However, some other experiments did not report signi¢cant change in the Lorentz number when the thickness of metal ¢lms varied.35 Hence, it remains inconclusive as to whether the validity of the Lorentz number indeed fails in thin metallic ¢lms. 3. THERMAL CONDUCTIVITY OF DIELECTRIC FILMS Dielectric thin ¢lms have wide applications in microelectronics, semiconductor lasers, and optical devices, and may serve as electrical insulators, optical coatings, and thermal barrier coatings. Knowledge of the thermal conductivity of these thin ¢lms is essential for the performance and reliability of these structures or devices. These thin ¢lms are typically deposited under highly nonequilibrium conditions, so their thermal properties may be very di¡erent from those in bulk form, due to the di¡erent structure, stoichiometry, and boundary scattering. This section discusses experimental data for the most common dielectric material, amorphous silicon dioxide (a-SiO2 Þ, as well as diamond ¢lms, thermal barriers, and optical coatings. Other reviews should also be consulted for wider coverage.1;2;4;20 3.1. Amorphous SiO2 Thin Films

Thermal Conductivity (W/m-K)

The thermal conductivity of a-SiO2 thin ¢lms has been investigated by many researchers through various experimental methods.3641 Figure 3 summarizes some reports on the thermal conductivity of a-SiO2 thin ¢lms perpendicular to the ¢lm plane (the cross-plane direction). As seen in this ¢gure, the thermal conductivity of a-SiO2 thin ¢lms is reduced in comparison to bulk in all cases. The large variation in thermal conductivity is most likely due to the strong dependence of microstructure on the processes used in preparing the samples. For example, the thermal

1.5 Sputtering, 0.5-2.0µm PECVD, 0.57-2.28µm

1

0.5

Orchard-Webb Brotzen et al. Goodson Kleiner et al. Bulk SiO2

LPCVD, 0.5µm

PECVD, 1.4µm

Lee et al. PECVD, 1.4µm

0 250

300

350

Temperature (K)

400

FIGURE 3 Experimental results of the cross-plane thermal conductivity as a function of temperature in amorphous SiO2 thin ¢lms (data from Refs. 36-41). The experimental data are labeled by the preparation methods and ¢lm thickness in m.

172 Chap. 1.7

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

ThermalConductivity(W/m-K)

conductivity of low-pressure chemical vapor deposition (LPCVD) SiO2 ¢lms by Goodson et al: is about four times larger than thermal conductivity of plasmaenhanced chemical vapor deposition (PECVD) SiO2 ¢lms by Brotzen et al: for ¢lms of comparable thickness.40;41 For a-SiO2 ¢lms, the structure variation is often re£ected by the mass density variations. Figure 4 lists the representative data on SiO2 ¢lms at room temperature for which mass density data are available. In general, higher mass density leads to higher thermal conductivity for a-SiO2 ¢lms. For example, SiO2 ¢lms grown through thermal oxidation have higher thermal conductivity than PECVD SiO2 ¢lms. Another cause for reduced thermal conductivity in a-SiO2 is the interfacial layer, where structural imperfections, such as growth defects, microvoids, lattice strain, and even surface contamination, tend to concentrate.37 41 Most of the experimental data showing that the thermal conductivity decreases with decreasing ¢lm thickness in a-SiO2 ¢lms can be explained by the existence of a thermal boundary resistance between the ¢lm and the substrate.37 41 One more thing to be pointed out is that the trends of thermal conductivity with temperature in Fig. 3 are di¡erent. Some data show that the thermal conductivity of a-SiO2 thin ¢lms increases with increasing temperature, similar to the behavior of bulk a-SiO2 . Yet there are also data suggesting that thermal conductivity of SiO2 decreases with increasing temperature, similar to the behavior of crystalline SiO2 (quartz). There are no satisfactory explanations for this contradiction. Recently, a new form of SiO2 , carbon^doped silicon dioxide (CDO), has attracted growing attention because its low permittivity may increase CMOS performance limited by the RC delay.42 The permittivity in CDO can be reduced from 4 to 2, and thus CDO is forecast to partially replace SiO2 as the gate material in microelectronics. In CDO the introduction of carbon can reduce mass density and permittivity as well as thermal conductivity. The thermal conductivity of CDO is shown in Fig. 4. This reduced thermal conductivity can impact the thermal management of ICs. 1.5 CDO SiO2

Thermal

PECVD

1

Sputtered

LPCVD

0.5

0 1000

Evaporated

1500

2000

3

2500

MassDensity(kg/m ) FIGURE 4 Mass density dependence of the cross-plane thermal conductivity of silicon dioxide and carbon-doped silicon dioxide (CDO) ¢lms at room temperature.1;42 The thickness of thermal, PECVD, sputtered, LPCVD and evaporated SiO2 ¢lms is 0.99m, 0.11 m, 1.5 m, 0.5 m, and 2.18 m, respectively. The thickness of CDO ¢lms is 0.25 m to 2.0 m.

Sec. 3

THERMAL CONDUCTIVITY OF DIELECTRIC FILMS

173

TABLE I Thermal Conductivity (W/m-K) of Optical Coatings

Film/Substrate

kFilm

kBulk

Direction of the Property

Film Thickness (m)

Ref.

TiO2 /silicon Al2 O3 /silicon MgF2 AlF3 /sapphire ZrO2 /sapphire ThO2 /sapphire CeF3 /sapphire ThF4 /sapphire Si3 N4 /silicon Si0:7 Al0: 3N/silicon Si0:6 Al0:4 NO/silicon BN/silicon SiC/silicon Ta2 O5 /silicon TiO2 /silica Ta2 O3 /silica Al2 O3 /silica HfO2 /silica Al2 O3 /silicon TiO2 /silicon

0.59 0.72 0.58 0.31 0.04 0.67 0.08 0.10 0.15 0.82 0.83 0.32 0.12 0.12 0.018 0.026 33 0.00077 1.1-1.7 2.1-6.1

7.4-10.4 20-46 14.6-30

Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane Cross-plane a * * * Cross-plane Cross-plane

0.060-1.246 0.173-0.462 0.209-0.583 0.194-0.544 0.151-0.465 0.174-0.396 0.128-0.357 0.162-0.506 0.5-2.0 0.5-2.0 0.5-2.0 0.5-2.0 0.5-2.0 0.5-2.0 b ** ** ** 0.5-2.0 0.5-2.0

43 43 43 43 43 43 43 43 46 46 46 46 46 46 44 44 44 44 36 36

a b

1.1-2.2 16-26

10

62(a axis) 25 7.4-10.4 20-46 20-46 7.4-10.4

Assume the thermal conductivity in the cross-plane same as the in-plane. 4-12 quaterwaves of optical thickness at 1.064m.

3.2. Thin Film Coatings A wide variety of dielectric thin ¢lms has attracted much attention for applications as optical coatings in various optical components, in which high optical power density may be encountered. The thermal conductivity of optical coatings is an important parameter in optical element design and damage estimation. Table 1 summarizes the thermal conductivity of commonly used optical coatings. Lambropoulos et al: measured oxide and £uoride ¢lms and observed a large di¡erence in thermal conductivity between thin ¢lms and bulk materials.43 Ristau and Ebert measured electron^beam-deposited ¢lms of Al2 O3 , TiO2 , HfO2 , and Ta2 O5 on fused-silica substrates and found that only Al2 O3 had a value close to the bulk. The other ¢lms had from one to several orders of magnitude lower thermal conductivity than the bulk values.44 Ogden et al: observed that thick (as thick as 85 m) ¢lms of Al2 O3 had an average thermal conductivity of 0.73 W/m-K compared with 30 W/m-K for bulk polycrystalline Al2 O3 .45 Henager and Pawlewicz measured sputtered oxide and nitride ¢lms and showed that thin-¢lm thermal conductivity is typically 10 to 100 times lower than the bulk values.46 The reduction in thermal conductivity of these ¢lms is normally attributed to the varied structure and boundary scattering. Thermal barrier coatings (TBCs) o¡er the potential to signi¢cantly increase the performance and lifetime of heat engines.47 50 In contrast to optical coatings, TBCs should have low thermal conductivity, because a high-temperature drop across the

174 Chap. 1.7

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

TBC is desired. Today, the standard TBC is partially stabilized zirconia (PSZ) because of its low thermal conductivity and superior bonding to the alloy or superalloy substrate.49;50 The thermal conductivity of PSZ is 0.4^1.2 W/m-K, depending on the doping oxides, such as Y2 O3 , CeO2 , and MgO2 .47;48 The PSZ usually exhibits a weak temperature dependence of thermal conductivity, especially at high temperature (>1000‡C). One way to reduce the thermal conductivity of PSZ is to replace some zirconium ions with heavier dopants, such as hafnium. It is reported that the thermal conductivity of Hf-doped yttria-stablized zirconia can be about 85% of its yttria-stablized zirconia counterpart.47 3.3. Diamond Films Passive CVD diamond layers have the potential to improve thermal management in optoelectronics and electronic microstructures because of their high thermal conductivity.1;51;52 The thermal conductivity of polycrystalline diamond ¢lms strongly depends on grain size, grain orientation, lattice imperfection, impurities, etc., which are governed by the details of the deposition process. The columnar-grained structure favors heat conduction normal to the diamond ¢lms. Verhoeven et al:52 observed a large degree of anisotropy in the thermal conductivity of polycrystalline diamond ¢lms, with the cross-plane thermal conductivity about one order of magnitude higher than its in-plane counterpart. Figure 5c compares the thermal conductivity of a highly-oriented diamond ¢lm to that of a random grain ¢lm, showing that the former has a much higher thermal conductivity than the latter.53 Heat conduction in polycrystalline diamond ¢lms can be modeled through the introduction of a mean free path caused by grain boundary scattering.1 4. THERMAL CONDUCTIVITY OF SEMICONDUCTOR AND SEMIMETAL THIN FILMS

ThermalConductivity(W/m-K)

In semiconductors the electron contribution to heat conduction is usually very small, depending on the doping concentration. In semimetals, however, both electrons and phonons may contribute to heat conduction. The most important representative for semiconductor materials is silicon. This section will ¢rst discuss the 1200 1000 800 600 400 200 0 50

100

150

200

250

300

350

Temperature(K)

FIGURE 5 SEM pictures of diamond ¢lms (a) with highly oriented structure and (b) randomly oriented structure. (c) Thermal conductivity along the diamond ¢lm with highly oriented structure (square) and randomly oriented structure (circle). The thickness of both samples is around 70 m. Data from Ref. 53 and the unpublished paper by D. Borca-Tasciuce et al.

Sec. 4 FILMS

THERMAL CONDUCTIVITY OF SEMICONDUCTOR AND SEMIMETAL THIN 175

thermal conductivity of silicon thin ¢lms in the forms of single-crystalline, polycrystalline, and amorphous states. The second part of this section will be dedicated to several semimetal thin ¢lms with potential application as thermoelectric materials. 4.1. Silicon Thin Films The thermal conductivity of single-crystalline silicon ¢lms is an important design parameter for silicon-on-insulator (SOI) ICs and single-crystalline silicon-membrane-based sensors and actuators. Goodson and co-workers have published a series of papers on the in-plane thermal conductivity of single-crystalline silicon ¢lms.54;55 Figure 6 summarizes the in-plane thermal conductivity of silicon thin ¢lms in the single-crystal, polycrystalline and amorphous forms. As seen in this ¢gure, the reduction in thermal conductivity of single-crystalline silicon thin ¢lms compared to bulk is very large at low temperatures but only moderate at high temperatures. The reduction in thermal conductivity is mainly attributed to interface or di¡use surface scattering.5456 Since the interface or surface scattering is not sensitive to temperature, whereas Umklapp scattering grows stronger with temperature, the relative impact of surface scattering is much larger at low temperatures than that at high temperatures. The e¡ects of boundary scattering on thermal conductivity of single-crystalline silicon can be traced to the study by Savvides and Goldsmid,57 who observed size e¡ects in ¢lms of about of 100 m after subjecting these ¢lms to proton irradiation. The onset of size e¡ects in such thick samples was attributed to the fact that short-wavelength phonons are strongly scattered by the implanted ions, while long-wavelength phonons, having a long mean free path, are subject to boundary scattering. At low temperatures impurity scattering, such as ion scattering, will play an important role in thermal transport in thin ¢lms. Figure 6 shows that the thermal conductivity of single-crystalline silicon thin ¢lm doped to 1019 cm3 is reduced by a factor of 2 at 20 K compared to the undoped sample. Polysilicon ¢lms can be deposited at high quality and are common in MEMS and microelectronics. Muller and co-authors measured heavily doped LPCVD polysilicon ¢lms, using microfabricated bridges.58 They found that the in-plane thermal conductivity ranged from 29 to 34 W/m-K. Volklein and Batles measured the lattice and electronic components of the in-plane thermal conductivity in polysilicon ¢lms heavily doped with phosphorus (51020 cm3 Þ; using a di¡erential method.59 They observed that the total thermal conductivity is around 29 W/m-K at temperatures above 200 K and the electronic component is less than 3%. More recently, Goodson’s group studied the in-plane thermal conductivity of polysilicon thin ¢lms with and without doping, shown in Fig. 6.60;61 As seen in this ¢gure, the thermal conductivity of polysilicon thin ¢lms is strongly reduced at all temperatures, compared to single-crystalline silicon. For a pure polysilicon ¢lm 200 nm thick, the thermal conductivity is about two orders of magnitude smaller than that of bulk silicon at temperatures below 100 K, and about 10 times lower than those of undoped single-crystalline silicon thin ¢lms. This big reduction in thermal conductivity is due mainly to phonon scattering at the grain boundaries, where the imperfection defects populate, and at interfaces and surfaces.60;61 Unlike bulk silicon and single-crystalline silicon ¢lms, the thermal conductivity of polysilicon ¢lms increases with increasing temperature in the plotted temperature range, similar to the trend of speci¢c heat. The undoped polysilicon thin ¢lm 200 nm thick has lower

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

Termal Conductivity (W/m-K)

176 Chap. 1.7

10

4

10

3

Undoped

3µm 3µm

10

2

10

1

3µm 0.35µm 0.2µm

Doped Si:H (1%), 0.52µm

10 10

Bu lk Single Crystal Polycrystal Amorphous Single Crystal

0

Si:H (20%), 0.22µm

-1 1

10

10

2

Temperature (K) FIGURE 6 Temperature dependence of thermal conductivity of single-crystal bulk silicon, single-crystal silicon thin ¢lms,55;56 polycrystalline silicon thin ¢lms,60;61 and amorphous silicon thin ¢lms.16 These curves are label by ¢lm thickness. The thermal conductivity is measured in the in-plane direction for single-crystal and polycrystalline silicon ¢lms, and in the cross-plane direction for amorphous silicon thin ¢lms. The hydrogen content in the amorphous silicon ¢lms is 1% and 20%, respectively.

thermal conductivity than the doped one 350 nm thick, as seen in this ¢gure. This indicates that the impurities, such as ions, are not the primary mechanism for phonon scattering in polysilicon ¢lms. However, it does not necessarily mean that boundary scattering is dominant because the microstructure also strongly depends on ¢lm thickness. Amorphous silicon has thermal properties quite di¡erent from those of singlecrystal or polycrystalline silicon due to its di¡erent structure. The introduction of hydrogen to amorphous silicon can greatly modify its electrical properties, and thus amorphous hydrogenated silicon has been widely used in solar cells and thin-¢lm transistors even though it has poor thermal conductivity.62 Goldsmid et al: measured a 1.15-m-thick amorphous silicon at room temperature and obtained a rather large thermal conductivity, 2.9 W/m-K.63 Pompe and Hegenbarth studied the temperature dependence of the thermal conductivity in a 26-m-thick sputtered amorphous silicon ¢lm in the temperature range of 2^50 K and found that the thermal conductivity plateau for the amorphous silicon ¢lm occurs at a higher temperature (30 K) than those of other amorphous dielectric ¢lms (10^15 K), such as Ge and As.64 Attaf et al. studied the e¡ects of hydrogen content on the thermal conductivity of amorphous silicon ¢lms and found a systematic trend of decreasing thermal conductivity for increasing hydrogen content. Besides the disordered lattice, the mass di¡erence between Si and H seems to further localize the vibration wave.65 However, Cahill et al: reported a much weaker dependence of the thermal conductivity on the hydrogen content, and part of their data is shown in Fig. 6.16 In disordered materials, such as amorphous silicon, heat transport by lattice vibration can be separated into two regimes. The lattice vibrations with low energy are wave-like, and thus phonons exist with well-de¢ned wave vector and wave velocity. On the other hand, Orbach66 proposed that a dominant fraction of high-energy lattice vibrations is localized and unable to contribute to heat trans-

Sec. 4 FILMS

THERMAL CONDUCTIVITY OF SEMICONDUCTOR AND SEMIMETAL THIN 177

port unless anharmonic forces are present. More recent studies suggested that although high-energy lattice vibrations do not have well-de¢ned wave vector and wave velocity, the dominant mechanism for heat conduction in amorphous silicon thin ¢lms should be the coupling between nearly degenerated, extended, but nonpropagating vibrations.16;67 4.2. Semimetal Thin Films Semimetal thin ¢lms, such as Bi- and Sb-based thin ¢lms, have potential application as thermoelectrics, which requires low thermal conductivity. Abrosimov et al:6;68 and Volklein and Kesseler69 measured the in-plane thermal conductivity of polycrystalline Bi thin ¢lms deposited through thermal evaporation, as well as other thermoelectric properties. Although bulk single-crystal Bi has a fairly small thermal conductivity, 5^10 W/m-K depending on the crystallographic direction,70 the measured thermal conductivity shows size dependence for ¢lms as thick as 1000 nm. Abrosimov et al.68 observed a peak in the thermoelectric ¢gure of merit for Bi ¢lms with a thickness 100 nm and a systematic shift of the peak toward large thickness as temperature decreases. Such a peak behavior, however, was not seen in Volklein and Kesseler’s data.69 Volklein and his co-workers also studied the inplane thermal conductivity and other thermoelectric thin ¢lms, including Sb thin ¢lms, Bix Sb1x thin ¢lms,71 and (Bi1x Sbx Þ2 Te3 thin ¢lms.72 For both Bi and Sb thin ¢lms, after subtracting the electronic contribution to the thermal conductivity according to the Wiedemann^Franz law, the phonon contribution to thermal conductivity increases with increasing temperature, similar to the behavior of many polycrystalline silicon thin ¢lms and diamond thin ¢lms. This implies that phonon^ phonon scattering is overplayed by the temperature-independent boundary scattering in the Bi and Sb thin ¢lms, even in the high-temperature range.

4.0

THERMAL CONDUCTIVITY (W/m-K)

3.5 3.0

Thickness [Film (nm)/Period (nm)] IrSb3/CoSb3 (175/6)

IrSb3/CoSb3 (225/75)

IrSb3/CoSb3 (205/14)

Ir0.5Co0.5Sb3 (150)

IrSb3/CoSb3 (160/16)

Ir4LaGe3Sb9 (Bulk)6

IrSb3/CoSb3 (140/25)

2.5 2.0 1.5 1.0 0.5 50

100

150 200 TEMPERATURE (K)

250

300

FIGURE 7 Cross-plane thermal conductivity of skutterudite thin ¢lms and superlattices.75 The numbers within the parentheses are the ¢lm thickness and the period thickness in nm.

178 Chap. 1.7

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

In the cross-plane direction, Baier and Volklein73 measured the thermal conductivity of Bi0:5 Sb1:2 Te3 ¢lms between 50 and 1000 nm, but no thickness dependence was reported. The thermal conductivity at room temperature is 0.37 W/m-K, lower than bulk alloys.74 Song et al:75 measured the thermal conductivity of polycrystalline CoSb3 and IrSb3 thin ¢lms and their alloy ¢lms. Figure 7 shows the temperature dependence of the thermal conductivity of these ¢lms and a comparison with their bulk counterparts. A signi¢cant reduction in thermal conductivity is observed in comparison with bulk counterparts, even for alloy ¢lms. More interestingly, the thermal conductivity of the alloy ¢lm is comparable to ¢lled skutterudites. The latter has been used to reduce the thermal conductivity of un¢lled skutterudites.76 5. SEMICONDUCTOR SUPERLATTICES Superlattice ¢lms consist of periodically alternating layers of two di¡erent materials stacked upon each other.77 Modern growth techniques, such as molecular-beam epitaxy (MBE) and metal-organic chemical vapor deposition (MOCVD), have enabled the fabrication of semiconductor superlattices with submonoatomic layer (ML) precision. Thermal transport in semiconductor superlattices has attracted considerable attention due to applications in thermoelectric devices11;12;78 82 and optoelectronic devices such as quantum well lasers and detectors.3;4 To increase the e⁄ciency of the thermoelectric devices, these ¢lms need to have low thermal conductivity. On the contrary, thin ¢lms with high thermal conductivity are desired to dissipate heat in semiconductor lasers and other optoelectronic devices.10 In this section we emphasize the thermal conductivity of semiconductor superlattices, in which heat is mainly carried by phonons. Metallic superlattices are also of interest for short-wavelength applications such as x-ray and deep ultraviolet lithography, and in magnetic data storage,83;84 although these studies will not be reviewed in detail here. The ¢rst experiment on the thermal conductivity of semiconductor superlattices was reported by Yao.85 He found that the in-plane thermal conductivity of GaAs/AlAs superlattices was smaller than the corresponding bulk values (obtained according to the Fourier law with the use of the properties of their bulk constituents). The anisotropy of thermal di¡usivity in superlattices was experimentally observed by Chen et al:, who found that the cross-plane thermal conductivity was four times smaller than that in the in-plane direction for short-period GaAs/AlAs superlattices used in semiconductor lasers.19 In recent years, extensive experimental data on the thermal conductivity of various superlattices emerged, including Bi 2 Te 3 /Sb 2 Te 3 , 86 88 GaAs/AlAs, 18;89;90 Si/Ge, 91 94 InAs/AlSb, 95 InP/InGaAs,96 CoSb3 /IrSb3 ,75 and PbTe-based superlattices.97;98 All these experiments con¢rmed that the thermal conductivities of the superlattices in both directions are signi¢cantly lower than the corresponding equivalent values calculated from the Fourier law using the bulk thermal conductivity of their constituent materials. In the cross-plane direction the thermal conductivity values can de¢nitely be reduced below that of their corresponding alloys. In the in-plane direction the reduction is generally above or comparable to that of their equivalent alloys, although a few experimental data indicate that thermal conductivity values lower than these of their corresponding alloys are possible.97 The period-thickness dependence of thermal conductivity may be di¡erent for

Sec. 5

SEMICONDUCTOR SUPERLATTICES

179

di¡erent superlattice groups and di¡erent growth techniques. For a GaAs/AlAs superlattice the di¡erence in the lattice constants between the adjacent layers is very small. As a consequence, the critical thickness for the formation of mis¢t dislocations is very large, and the interfaces can have excellent quality, typically consisting of only 1^3 MLs mixing region with some long-range lateral terraces.99;100 In this case the interface quality can remain almost identical over the considered range of period thickness. Hence, the relative e¡ects of interface scattering or interface resistance on the superlattice thermal conductivity will decrease with increasing period thickness. The experimental data for GaAs/AlAs in the in-plane direction by Yao85 and in the cross-plane direction by Capinski et al:18 seem to support this idea. Many other superlattice groups, such as Bi2 Te3 /Sb2 Te3 and InAs/AlSb, also exhibit behavior similar to GaAs/AlAs superlattices. Although Si and Ge have a relatively large di¡erence in lattice constant, a Six Ge1 x /Siy Ge1 y superlattice may have a critical thickness much larger than that of superlattice Si/ Ge, depending on the composition. Huxtable et al: have shown that for superlattice Si /Si0:7 Ge0:3 the thermal conductivity scales almost linearly with interface density.96 An interesting observation made experimentally in Bi2 Te3 /Sb2 Te3 superlattices86 (shown in Fig. 8a) and less systematically in GaAs/AlAs superlattices (shown in Fig. 8b)18 is that in the very thin period limit the thermal conductivity can recover as the period thickness decreases, and thus a minimum exists in the thermal conductivity when plotted as a function of the period thickness. Unlike GaAs/AlAs and Bi2 Te3 /Sb2 Te3 superlattices, Si/Ge superlattices have a small critical thickness, on the order of 10 nm. The data on Si/Ge superlattices by Lee et al:91 and by Borca^Tasciuc et al:92 plotted in Fig. 9, show that the thermal conductivity initially increases with period thickness and then drops as the period thickness is increased beyond 10 nm. This is presumably due to the extension of mis¢t dislocations for periods larger than the critical thickness. The temperature dependence of thermal conductivity could be used to dissect the contribution of di¡erent scattering mechanisms, as shown in Fig. 10. It is well known that the thermal conductivity of bulk semiconductor materials drops very fast with increasing temperature in the relatively high temperature range due to phonon^phonon scattering.101;102 In superlattices the presence of interface scatter15

1 Venkatasubramanian 2000 Ymasaki et al. 1998

MPI NRL

0.8

k (W/m-K )

2

3

10

k (W/m-K)

Sb Te

0.6 BiSbTe3 Alloy 0.4

5

0.2 (a)

0 10

Bi2Te3/Sb2Te3SL

100

Period Thickness (Å)

1000

GaAs/AlAs SL

(b)

0

1

10

100

Period Thickness (Å)

FIGURE 8 Cross-plane thermal conductivity as a function of period thickness for (a) Bi2 Te3 /Sb2 Te3 SLs and (b) GaAs/AlAs SLs at T=300 K.18;86;87

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES THERMAL CONDUCTIVITY (W/mK)

180 Chap. 1.7

5 203K 80K 200K (Lee et al.)

4

3

2

1

0

50

100

150

200

250

300

Period Thickness (Å)

Thermal Conductivity (W/m K)

FIGURE 9 Cross-plane thermal conductivity as a function of period thickness in Si/Ge SLs.91;92

100 GaAs/AlAs, In-plane GaAs/AlAs, Cross-plane Si/Ge, Cross-plane Si/Ge, In-plane

10

1 100

150

200

250

300

Temperature (K) FIGURE 10 In-plane and cross-plane thermal conductivities of the Si/Ge and GaAs/AlAs SLs as a function of temperature. One period of Si/Ge SL consists of Si(80 A)/Ge(20 A). In one period of the GaAs/AlAs SLs, the GaAs and AlAs layers have the same thicknes, and the period thickneses are 140 A and 55 A for the GaAs/AlAs SLs used in in-plane and cross-plane directions, respectively.18;89;94

ing, as well as dislocation scattering, will signi¢cantly modify the temperature dependence of thermal conductivity. The interface roughness and substitution alloying may account for the di¡use interface scattering, which is not sensitive to temperature. For both in-plane and cross-plane directions of a GaAs/AlAs superlattice, the thermal conductivity was found to decrease with increasing temperature at the intermediate temperature range, with a slope much smaller than that of the corresponding bulk materials, especially in the cross-plane direction.89;90 In the cross-plane direction of Si/Ge and Six Ge1 x /Siy Ge1 y , the opposite trend was observed, i.e. the thermal conductivity increases with increasing temperature.91 96 In this case, the temperature-dependent scattering mechanisms, such as Umklapp scattering, do not contribute too much to heat conduction, and the interface scattering and dislocation scattering that are less sensitive to temperature dominate the trans-

Sec. 6

SEMICONDUCTOR SUPERLATTICES

181

port. Clearly, the mismatch in acoustic impedance or, more generally, density, speci¢c heat, force, and lattice constants between Si and Ge is more than that of GaAs and AlAs, and a larger interface scattering strength is expected for Si/Ge superlattices. This also contributes to the weaker interface scattering in GaAs/AlAs relative to that in Si/Ge superlattices. The e¡ects of the growth and annealing temperatures on the thermal conductivity of InAs/AlSb superlattices were studied by Borca-Tasciuc and co-workers and they observed that the thermal conductivity of this superlattice system decreased with increasing annealing and growth temperature.95 On the other hand, Si/Ge and Gequantum-dot superlattices seem to show an opposite trend.21;80 Although it is known that the growth and annealing temperature will a¡ect the interfaces and defects in superlattice, the detailed mechanisms are still not clear. Current models on phonon transport in SLs are generally divided into three groups. The ¢rst group treats phonons as totally incoherent particles.22;23;103 The thermal conductivity is usually calculated with the Boltzmann transport equation with boundary conditions involving di¡use interface scattering. These particle models can ¢t experimental data of several SL systems in the thick-period range. Because the wave features of phonons in SLs are not considered, they fail to explain the thermal conductivity recovery in the short-period limit with period thickness less than 5 (bulk) unit cells. The second group of models treats phonons as totally coherent waves, and thus phonons in di¡erent layers of a SL are coherently correlated, and SL phonon bands can be formed due to the coherent interference of the phonon waves transporting toward and away from the interfaces.104;105 108 Under this picture thermal conductivity in SLs is usually calculated through the phonon dispersion relation in SLs. The calculated conductivity typically ¢rst decreases with increasing period thickness and then approaches a constant with period thickness beyond about 10 MLs. The predictions of the coherent phonon picture at the very thin period limit is similar to some experimental observations, but the thick-period behavior is contrary to the experimental results observed in many SLs, such as GaAs/AlAs and Bi2 Te3 /Sb2 Te3 , which show an increase in thermal conductivity with increasing period thickness.86;87;89 The third group of traditional models involves lattice dynamics, which usually leads to a temperature-dependent thermal conductivity similar to that of bulk crystalline materials, contrary to most experimental observations. Apparently, neither coherent wave models nor incoherent particle models alone can explain the period-thickness dependence of thermal conductivity in SLs over the full period-thickness range because each of them deals with an extreme case. Simkin and Mahan proposed a modi¢ed lattice dynamics model with a complex wave vector involving the bulk phonon mean free path, and they predicted a minimum of thermal conductivity in the cross-plane direction.109 However, the calculated thermal conductivity reduction is still lower than the experimental data. Very recently, a partially coherent phonon transport model proposed by Yang and Chen24 combines the e¡ects of phonon con¢nement and di¡use interface scattering on the thermal conductivity in superlattices, and is applicable to phonon transport in the partially coherent regime. The period thickness dependence and temperature dependence of the thermal conductivity in the GaAs/AlAs superlattices can be well explained by this model.

182 Chap. 1.7

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

6. CONCLUSIONS In this chapter we have discussed the experimental data of thermal conductivity in metallic, dielectric, semiconductor, and semimetal thin ¢lms and semiconductor superlattices. The major points are as follows: 1. For polycrystalline and single-crystalline ¢lms, the thermal conductivity is dramatically reduced compared to their bulk counterparts. Phonon and electron scattering at boundaries, grain boundaries, or interfaces plays a crucial role in thermal conductivity reduction. The modi¢ed microstructure in thin ¢lms also makes signi¢cant contribution to the reduction in thermal conductivity. 2. For amorphous ¢lms with very short phonon mean free path, the microstructures, particularly mass density and stoichiometry that depend strongly on the processing conditions, play a more signi¢cant role in thermal conductivity. Most cross-plane thickness dependence data for ¢lms processed under similar conditions can be explained by the interfacial thermal resistance between the ¢lm and the boundary rather than size e¡ects arising from the long phonon mean free path. 3. Thermal conductivity in both the in-plane and cross-plane directions of superlattices is signi¢cantly reduced compared to the corresponding bulk values. Some experimental data show a minimum in thermal conductivity when the superlattice period thickness is around a few MLs. A partially coherent phonon heat conduction model, combining the e¡ects of phonon con¢nement and di¡use interface scattering on the thermal conductivity in superlattice, can explain the period-thickness dependence and temperature dependence of the thermal conductivity in the GaAs/AlAs superlattices. Compared to the large body of work on the electrical properties in thin ¢lms, research on thermal transport is still relative scarce. Many challenges should be addressed in future studies, such as measurement techniques, thermal conductivity modeling, and deeper understanding of the phonon scattering mechanisms. The relationship between the microstructures, interface conditions, and thermal conductivity should be emphasized in future experimental research. 7. ACKNOWLEDGMENTS We would like to acknowledge the support from DoD/ONR MURI on Thermoelectrics, DOE (DE-FG02-02ER45977) on heat transfer in nanostructures, and NSF (CTS-0129088) on nanoscale heat transfer modeling. We also would like to thank contributions of current and former members in G. Chen’s group working on thin-¢lm thermophysical properties, particularly Prof. T. Borca-Tasciuc, Diana Borca-Tasciuc, W.L. Liu, and D. Song, and we would like to thank C. Dames for critically reading the manuscript. 8. REFERENCES 1.

K. Goodson and Y. Ju Heat Conduction in Novel Electronic Films Annu. Rev. Mater. Sci. 29, 261^ 293 (1999).

Sec. 8 2. 3. 4. 5. 6. 7.

8. 9. 10. 11. 12. 13. 14. 15. 16. 17.

18.

19. 20. 21. 22. 23. 24. 25.

26. 27. 28. 29. 30.

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183

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31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50.

51. 52.

53.

54.

55.

56.

THERMAL CONDUCTIVITY OF THIN FILMS AND SUPERLATTICES

Tantalum Adhesion Layers on the Properties of Sol-Gel Derived SrBi2 Ta2 O9 Thin Films J. Appl. Phys. 92, 1511^1517 (2002). P. Nath and K. L. Chopra Experimental Determination of the Thermal Conductivity of Thin Films Thin Solid Films 18, 29^37 (1973). V. Wachter and F. Volklein Method for the Determination of the Thermal Conductivity and the Thermal Di¡usivity of Thin Metallic Films Exp. Tech. Phys. 25, 425^431 (1977). K. Fuchs The Conductivity of Thin Metallic Films According to the Electron Theory of Metals Proc. Camb. Phil. Soc. 34, 100^108 (1938). T. Q. Qiu and C. L. Tien Size E¡ects on Nonequilibrium Laser Heating of Metal Films ASME J. Heat Trans. 115, 842^847 (1993). T. Starz, U. Schmidt, and F. Volklein Microsensor for in Situ Thermal Conductivity Measurements of Thin Films Sensors and Materials 7, 395^403 (1995). S. M. Lee, D. G. Cahill, and T. H. Allen Thermal Conductivity of Sputtered Oxide Films Phys. Rev. B 52, 253^257 (1995). M. B. Kleiner, S. A. Kuhn, and W. Weber Thermal Conductivity Measurements of Thin Silicon Dioxide Films in Integrated Circuits IEEE Trans. Electron Dev. 43, 1602^1609 (1996). J. H. Orchard-Webb A New Structure for Measuring the Thermal Conductivity of Integrated Circuit Dielectrics in Proc. IEEE Int. Conf. on Microelectronic Test Structures (1991), pp. 41^45. H. A. Schafft, J. S. Suehle, and P. G. A. Mirel Thermal Conductivity Measurements of Thin-Film Silicon Dioxide in Proc. IEEE Int. Conf. on Microelectronic Test Structures (1989), pp. 121^125. K. Goodson, M. Flik, L. Su, and D. Antoniadis Annealing-temperature Dependence of the Thermal Conductivity of LPCVD Silicon-dioxide Layers IEEE Electron Device Lett. 14, 490-492 (1993). R. F. Brotzen, P. J. Loos, and D. P. Brady Thermal Conductivity of Thin SiO2 Films Thin Solid Films 207, 197^201 (1992). D. G. Cahill, W. K. Ford, K. E. Goodson, G. D. Mahan, A. Majumdar, H. J. Maris, R. Merlin, and S. R. Phillpot Nanoscale Thermal Transport Appl. Phys. Rev. 93, 1^30 (2003). J. Lambropoulos, M. Jolly, C. Amsden, S. Gilman, M. Sinicropi, D. Diakomihalis, and S. Jacobs Thermal conductivity of Dielectric Thin Films J. Appl. Phys. 66, 4230^4242 (1989). D. Ristau and J. Ebert Development of a Thermographic Laser Calorimeter Appl. Opt. 25, 4571^ 4578 (1986). T. Ogden, A. Rathsam, and J. Gilchrist Thermal Conductivity of Thick Anodic Oxide Coatings on Aluminum Mater. Lett. 5, 84^87 (1987). C. Henager and W. Pawlewicz, Thermal Conductivities of Thin, Sputtered Optical Films, Appl. Opt. 32, 91-101 (1993). R. Taylor, X. Wang, and X. Xu Thermophysical Properties of Thermal Barrier Coatings Surf. and Coat, Techn, 120/121, 89^95 (1999). R. Vassen, X. Cao, and D. Stover Improvement of New Thermal Barrier Coating Systems using a Layered or Graded Structure Ceram. Eng. Sc. Proc. 22, 435^442 (2001). D. Clarke Materials Selection Guidelines for Low Thermal Conductivity Thermal Barrier Coatings Surf. and Coat. Techn. 163/164, 67-74 (2003). U. Schulz, C. Leyens, K. Fritscher, M. Peters, B. Saruhan-Brings, O. Lavigne, J. Dorvaux, R. Mevrel, and M. Caliez Some Recent Trends in Research and Technology of Advanced Thermal Barrier Coatings Aerospace Sc. and Techn. 7, 73^80 (2003). K. Goodson, O. Kading, M. Rosler, and R. Zachai Experimental Investigation of Thermal Conduction Normal to Diamond-silicon Boundaries J. Appl. Phys. 74, 1385^1392 (1995). H. Verhoeven, E. Boettger, A. Floter, H. Reiss, and R. Zachai Thermal Resistance and Electrical Insulation of Thin low-temperature-deposited Diamond Films Diamond Rel. Mater. 6, 298^302 (1997). S. D. Wolter, D. A. Borca-Tasciuc, G. Chen, N. Govindaraju, R. Collazo, F. Okuzumi, J. T. Prater, and Z. Sitar Thermal Conductivity of Epitaxially Textured Diamond Films Diamond Rel. Mater. 12, 61^64 (2003). M. Asheghi, M. N. Touzelbaev, K. Goodson, Y. Leung, and S. Wong Temperature-dependent Thermal Conductivity of Single-crystal Silicon Layers in SOI Substrates J. Heat Trans. 120, 30^36 (1998). M. Asheghi, K. Kurabayashi, K. Goodson, R. Kasnavi, and J. Plummer Thermal Conduction in Doped Single-crystal Silicon Films, in Proc. 33rd ASME/AIChE National Heat Transfer Conf., (Albuquerque, NM, 1999). D. Song, Phonon heat conduction in nano and micro-porous thin ¢lms Ph. D. Thesis, University of California at Los Angeles, Department of Mechanical and Aerospace Engineering, 2003.

Sec. 8

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185

57. N. Savvides and H. J. Goldsmid The E¡ect of Boundary Scattering on the High-temperature Thermal Conductivity of Silicon J. Phys. C: Solid State Phys. 6, 1701^1708 (1973). 58. Y. C. Tai, C. H. Mastrangelo, and R. S. Muller , Thermal Conductivity of Heavily Doped Lowpressure Chemical Vapor Deposited Polycrystalline Silicon Films, J. Appl. Phys. 63, 1442^7 (1988). 59. F. Volklein and H. Batles A Microstructure for Measurement of Thermal Conductivity of Polysilicon Thin Films J. Microelectromech. Syst. 1, 194^196 (1992). 60. S. Uma, A. McConnell, M. Asheghi, K. Kurabayashi, and K. Goodson Temperature-dependent Thermal Conductivity of Undoped Polycrystalline Silicon Layers Int. J. Thermophys. 22, 605^616 (2001). 61. A. McConnell, U. Srinivasan, M. Asheghi, and K. Goodson Thermal Conductivity of Doped Polysilicon J. Microelectromech. Syst. 10, 360-369 (2001). 62. R. Neville, Solar Energy Conversion: The Solar Cell, (New York, Elsevier, 1995). 63. H. Goldsmid, M. Kaila, and G. Paul Thermal conductivity of amorphous silicon Phys. Status Sol. A 76, K31^33 (1983). 64. G. Pompe and E. Hegenbarth Thermal Conductivity of Amorphous Si at Low Temperatures Phys. Status Sol. B 147, 103^108 (1988). 65. A. Attaf, M. S. Aida and L. Hadjeris Thermal Conductivity of Hydrogenated Amorphous Silicon Solid State Commun. 120, 525^530 (2001). 66. R. Orbach Variational Transport in Disordered Systems Philos. Mag. B 65, 289^301 (1992). 67. P. B. Allen and J. L. Feldman Thermal Conductivity of Disordered Harmonic Solids Phys. Rev. B 48, 12581^12588 (1993). 68. V. M. Abrosimov, B. N. Yegorov, and N. S. Lidorenko An Investigation of the Thermoelectric Figure of Merit of Bismuth Films Radio Eng. Electro. Phys. 9, 1578^1579 (1971). 69. F. Volklein and E. Kesseler, Thermal Conductivity and Thermoelectric F and Figure of Merit of Bi1 x Sbx ¢lms with 0 < x 0.3, Phys. Stat. Sol. (a) 81, 585^596 (1984). 70. C. F. Gallo, B. S. Chandrasekhar, and P. H. Sutter Transport Properties of Bismuth Single Crystals J. Appl. Phys. 34, 144 (1963). 71. F. Volklein and E. Kessler Analysis of the Lattice Thermal Conductivity of Thin Films by Means of a Modi¢ed Mayadas-Shatzkes Model: The Case of Bismuth Films Thin Solid Films 142, 169^181 (1986). 72. F. Volklein, V. Baier, U. Dillner, E. Kessler Thermal Conductivity and Di¡usivity of a Thin Film SiO2 /Si3 N4 Sandwich System Thin Solid Films 188, 27^33 (1990). 73. V. Baier and F. Volklein Thermal Conductivity of Thin Films Phys. Stat. Sol. (a) 118, K 69 (1990). 74. H. J. Goldsmid Thermoelectric Refrigeration (Plenum Press, New York, 1964). 75. D. W. Song, W. L. Liu, T. Zeng, T. Borca-Tasciuc, G. Chen, C. Caylor, and T. D. Sands, Thermal Conductivity of Skutterudite Thin Films and Superlattices, Appl. Phys. Lett. 77, 3854^3856 (2000). 76. G. Nolas, G. Slack, D. Morelli, T. Tritt, and A. Ehrlich The E¡ect of Rare-earth Flling on the Lattice Thermal Conductivity of Skutterudites J. Appl. Phys. 79, 4002^4008 (1996). 77. L. Esaki and R. Tsu Superlattice and Negative Di¡erential Conductivity in Semiconductors IBMJ. Research and Development 14, 61^61 (1970). 78. G. Chen Phonon Heat Conduction in Low-dimensional Structures Semiconductors and Semimetals 71, 203^259 (2001). 79. C. Weisbuch and B. Vinter, Quantum Semiconductor Structures (Academic Press, San Diego, CA, 1991). 80. G. Chen, B. Yang, and W. L. Liu Engineering Nanostructures for Energy Conversion in Heat Transfer and Fluid Flow in Microscale and Nanoscale Structures Wit Press, Southampton, UK, edited by M. Faghri and B. Sunden, pp. 45^91, 2003. 81. T. M. Tritt, ed., Recent Trend in Thermoelectric Materials Research in Semiconductor and Semimetals 69^71 (Academic Press, San Diego, 2001). 82. R. Venkatasubramanian, E. Siivola, T. Colpitts, and B. O’Quinn Thin-¢lm Thermoelectric Devices with High Room-temperature Figures of Merit Nature 413, 597^602 (2001). 83. J. Inoue, H. Itoh, S. Maekawa, Transport properties in magnetic superlattices, J. Phys. Soc. Japan 61, 1149^1152 (1992). 84. F. Tsui, B. Chen, J. Wellman, C. Uher, and R. Clarke Heat conduction of (111) Co/Cu superlattices J. Appl. Phys. 81, 4586^4588 (1997). 85. T. Yao Thermal properties of AlAs/GaAs superlattices Appl. Phys. Lett. 51, 1798^1800 (1987). 86. R. Venkatasubramanian Lattice Thermal Conductivity Reduction and Phonon Localizationlike Behavior in Superlattice Structures, Phys. Rev. B 61, 3091^3097 (2000).

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87. I. Yamasaki, R. Yamanaka, M. Mikami, H. Sonobe, Y. Mori, and T. Sasaki Thermoelectric Properties of Bi2 Te3/Sb2Te3 Superlattice Structure in Proc. 17th Int. Conf. on Thermoelectrics, ICT’98 (1998), pp. 210^213. 88. M. N. Touzelbaev, P. Zhou, R. Venkatasubramanian, and K. E. Goodson Thermal Characterization of Bi2 Te3 /Sb2Te3 Superlattices J. Appl. Phys. 90, 763^767 (2001). 89. X. Y. Yu, G. Chen, A. Verma, and J. S. Smith Temperature Dependence of Thermophysical Properties of GaAs/AlAs Periodic Structure Appl. Phys. Lett. 67, 3554^3556 (1995). 90. W. S. Capinski and H.J., Maris Thermal Conductivity of GaAs/AlAs Superlattices Physica B 219&220, 699^701 (1996). 91. M. Lee, D. G. Cahill, and R. Venkatasubramanian Thermal Conductivity of Si-Ge Superlattices Appl. Phys. Lett. 70, 2957^2959 (1997). 92. T. Borca-Tasciuc, W. L. Liu, T. Zeng, D. W. Song, C. D. Moore, G. Chen, K. L. Wang, M. S. Goorsky, T. Radetic, R. Gronsky, T. Koga, and M. S. Dresselhaus Thermal Conductivity of Symmetrically Strained Si/Ge Superlattices Superlattices and Microstructures 28, 119^206 (2000). 93. W. L. Liu, T. Borca-Tasciuc, G. Chen, J. L. Liu, and K. L. Wang Anisotropy Thermal Conductivity of Ge-quantum Dot and Symmetrically Strained Si/Ge Superlattice J. Nanosc. Nanotechn. 1, 39^42 (2001). 94. B. Yang, W. L. Liu, J. L. Liu, K. L, Wang, and G. Chen Measurements of Anisotropic Thermoelectric Properties in Superlattices Appl. Phys. Lett. 81, 3588^3590 (2002). 95. T. Borca-Tasciuc, D. Achimov, W. L. Liu, G. Chen, H. Ren, C. H. Lin, and S. S. Pei Thermal Conductivity of InAs/AlSb Superlattices Microscale Thermophys. Eng. 5, 225^231 (2001). 96. S. T. Huxtable, A. Abraham, C. L. Tien, A. Majumdar, C. LaBounty, X. Fan, G. Zeng, J. E. Bowers, A. Shakouri, and E. Croke, Thermal Conductivity of Si/SiGe and SiGe/SiGe Superlattices Appl. Phys. Lett. 80, 1737^1739 (2002). 97. H. Beyer, J. Nurnus, H. Bottner, Roch T Lambrecht, and G. Bauer Epitaxial Growth and Thermoelectric Properties of Bi2 Te3 Based Low Dimensional Structures Appl. Phys. Lett. 80, 1216^1218 (2000). 98. T. Harman, P. Taylor, M. Walsh, and B. LaForge Quantum Dot Superlattice Thermoelectric Materials and Devices Science 297, 2229^2232 (2002). 99. D. Gammon, B.V. Shanabrook, and D. S. Katzer Excitons, Phonons, and Interfaces in GaAs/AlAs Quantum-well Structures Phys. Rev. Lett. 67, 1547^1550 (1991). 100. T. Ruf, J. Spitzer, V. F. Sapega, V. I. Belitsky, M. Cardona, and K. Ploog Interface Roughness and Homogeneous Linewidths in Quantum Wells and Superlattices Studied by Resonant Acousticphonon Raman Scattering Phys. Rev. B 50, 1792^1806 (1994). 101. J. M. Ziman Electrons and Phonons (Clarendon, Oxford, 2001). 102. S. Sze, Physics of Semiconductor Devices (Wiley, New York, 1981). 103. S. G. Walkauskas, D. A. Broido, K. Kempa, and T. L. Reinicke Lattice Thermal Conductivity of Wires J. Appl. Phys. 85, 2579^2582 (1999). 104. P. Hyldgaard and G. D. Mahan Phonon Superlattice Transport Phys. Rev. B 56, 10754^10757 (1997). 105. S. Tamura, Y. Tanaka, and H. J. Maris Phonon Group Velocity and Thermal Conduction in Superlattices Phys. Rev. B 60, 2627^2630 (1999). 106. W. E. Bies, R. J. Radtke, and H. Ehrenreich Phonon Dispersion E¡ects and the Thermal Conductivity Reduction in GaAs/AlAs Superlattices J. Appl. Phys. 88, 1498^1503 (2000). 107. A. A. Kiselev, K. W. Kim, and M. A. Stroscio Thermal Conductivity of Si/Ge Superlattices: A Realistic Model with a Diatomic Unit Cell Phys. Rev. B 62, 6896^6999 (2000). 108. B. Yang and G. Chen Lattice Dynamics Study of Anisotropic Heat Conduction in Superlattices Microscale Thermophys. Eng. 5, 107^116 (2001). 109. M. V. Simkin and G. D. Mahan Minimum Thermal Conductivity of Superlattices Phys. Rev. Lett. 84, 927^930 (2000).

Chapter 2.1

MEASUREMENT TECHNIQUES AND CONSIDERATIONS FOR DETERMINING THERMAL CONDUCTIVITY OF BULK MATERIALS Terry M. Tritt Department of Physics and Astronomy, Clemson University, Clemson, SC, USA

David Weston Department of Physics and Astronomy, Clemson University, Clemson, SC, USA Michelin Americas Research and Development Corporation, Greenville, SC, USA

1. INTRODUCTION The accurate measurement and characterization of the thermal conductivity of bulk materials can pose many challenges. For instance, loss terms of the heat input intended to £ow through the sample usually exist and can be most di⁄cult to quantify. This chapter will provide an overview of the more typical measurement and characterization techniques used to determine the thermal conductivity of bulk materials. Some of the potential systematic errors that can arise and the corrections that need to be considered will be presented. This overview is not intended to serve as a complete description of all the available measurement techniques for bulk materials, of which there are many. However, it should provide an introduction and summary of the characterization and measurement techniques of thermal conductivity of bulk materials and give an extensive reference set for more in-depth

188 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

dialogue of the concepts and techniques. In addition, this overview should serve as an indication of the care that must be taken in performing these measurements. Many methods exist for the determination or measurement of thermal conductivity of a material, such as the steady-state (absolute or comparative) technique,1 the 3! technique,2 and the thermal di¡usivity measurement.3 Each of these techniques has its own advantages as well as its inherent limitations, with some techniques more appropriate to speci¢c sample geometry, such as the 3! technique for thin ¢lms. The 3! technique and methods for the measurement of thermal conductivity of thin ¢lms is discussed in detail in a later chapter.4 Therefore, this chapter will focus on the measurement techniques that are more appropriate for ‘‘bulk-like’’ solid-state materials. The techniques presented will include: the more common steady-state method, the comparative technique, the radial £ow method, the laser £ash di¡usivity method (for high temperatures), the ‘‘pulsed power or Maldonado technique,’’5 and the parallel thermal conductance (PTC) technique6 (for single-crystal needle-like samples). Thermal conductivity measurements are di⁄cult to make with relatively high accuracy, certainly better than within 5%. Many excellent texts and techniques discuss in detail many of the corrections and potential errors one must consider, and the reader is referred to these references.710 A word of caution is extended to those who are just beginning to perform thermal conductivity measurements. Only thorough understanding of the issues related to these measurements coupled with careful experimental design will yield the desired goal of highly reliable thermal conductivity measurements. Extensive e¡orts were expended in the late 1950s and 1960s in relation to the measurement and characterization of the thermal conductivity of solid-state materials. These e¡orts were made by a generation of scientists, who for the most part are no longer active, and this expertise would be lost to us unless we are aware of the great strides they made during their time. They did not have the advantage of computer data acquisition and had to painstakingly acquire the data through careful and considerate measurement techniques. The same issues are prevalent today and the same care has to be employed, yet we have many advantages, such as high-speed, highdensity data acquisition. Hopefully, this chapter will serve not only as a testament to those researchers of past generations whose great care in experimental design and thought still stands today but as an extensive resource for the next-generation researchers. Hopefully, the reader will gain a deeper appreciation of these points in the following pages. Readers are encouraged to delve into the papers of authors such as G. White, R. Berman, G. Slack, and R. Pohl, as well as many other superb experimentalists of their age. An excellent and extensive reference for thermal conductivity measurements can be found in Vol. 1 of Ref. 7. 2. STEADY-STATE METHOD (ABSOLUTE METHOD) Determination of the thermal conductance of a sample is a solid-state transport property measurement in which a temperature di¡erence (T ) across a sample is measured in response to an applied amount of heating power. This is essentially a measure of the heat £ow through the sample. The thermal conductivity (Þ is given by the slope of a power versus T sweep at a ¢xed base temperature with the dimensions of the speci¢c sample taken into account. The thermal conductivity as derived from a typical ‘‘steady-state’’ measurement method is

Sec. 2

STEADY-STATE METHOD (ABSOLUTE METHOD)

TOT ¼ PSAM LS =AT ;

189

ð1Þ

where TOT is the total thermal conductivity, PSAM is the power £owing through the sample, LS is the length between thermocouples, T is the temperature di¡erence measured, and A is the cross-sectional area of the sample through which the power £ows. 2.1. Overview of Heat Loss and Thermal Contact Issues However, determination of P SAM is not such a simple task. Typically, an input power, PIN , is applied to one end of the sample, and the power through the sample is PSAM ¼ PIN PLOSS ;

ð2Þ

where PLOSS is the power lost to radiation, heat conduction through gases or through the connection leads, or losses due to heat convection currents. The losses can be substantial unless su⁄cient care is taken in the design of the measurement apparatus and setup. These losses cannot be completely eliminated, but as stated an appropriate experimental design would include design considerations to minimize or su⁄ciently account for each loss term. For example, the thermocouple wires should be small diameter (0.001 inch) and possess low thermal conductivity, such as

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76,1.

FIGURE 1 Diagram of the steady-state thermal conductivity method used in one of our laboratories at Clemson University (TMT). Small copper wires (£ags) are attached to the samples on which the Cn^Cr thermocouples (0.001 inch diameter) are attached. A thin resistance heater (100 strain gauge) is attached to the top of the sample for the power source, I2 R. Phosphor bronze current leads [# 38 (0.004’)] are attached to the strain gauge resistor heater. The typical sample size is 2-3 mm for the width and/or thickness, and the total sample length is approximately 6^10 mm. (We acknowledge Prof. C. Uher, Univ. of Michigan, for mounting suggestions).

190 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

chromel or constantan wire. Also, we recommend using phosphor bronze (0.004 inch) lead wires for the input heater power. Phosphor bronze yields a relatively low thermal conductivity material, yet one that also has reasonable values of electrical conductivity. Heat loss through the connection wires of the input heater or the thermocouple leads can be calculated and an estimate obtained for this correction factor, which is typically less than 1^2% in a good experimental design. Correction issues related to convection or radiation losses can be more di⁄cult to quantify. An illustration of a sample mounted for steady-state thermal conductivity measurements is shown in Fig. 1. The heater power is supplied by I 2 R Joule heating of a 100- strain gauge resistance heater attached to the top of the sample. The complete description of the sample mounting and measurement techniques as well as a thorough description of the apparatus has been given previously.11 One advantage of this speci¢c apparatus is that it is mounted on a removable puck system attached to a closed-cycle refrigerator system for varying the temperature. This allows the sample to be mounted outside the apparatus and then essentially ‘‘plugged’’ into the measurement system, meaning little ‘‘downtime’’ of the apparatus. The measurement sequence, temperature control and data acquisition are obtained by a high-density computer-controlled experimental data acquisition program that uses Labview software. The steady-state thermal conductivity technique requires uniform heat £ow through the sample ; therefore, excellent heat sinking of the sample to the stable temperature base as well as the heater and thermocouples to the sample is an absolute necessity. Kopp and Slack discuss the subject of thermal anchoring and the associated errors quite thoroughly.12 It is strongly suggested that each researcher (and especially students) de¢nitely test any technique (and their mounting skills) by measuring known standards and comparing values. Insu⁄cient thermal anchoring can be di⁄cult to detect except by experienced researchers. There are, however, a few systematic ‘‘checks’’ that can be performed to rule out errors due to poor thermal anchoring. For example, thermal conductivity measurements are very important for evaluating the potential of thermoelectric materials.13 Two papers give excellent reviews of the issues related to accurate measurements of the electrical and thermal transport properties of thermoelectric materials, and readers are encouraged to examine them.14;15 The checks previously mentioned typically relate to simultaneously measuring the thermopower () where VSAM ¼ T ; using separate sample voltage leads attached to the sample. If a signi¢cant time lag exists between changes in sample voltage and changes in the temperature gradient (measured by the thermocouples), then this suggests a problem with thermal anchoring. Since the sample is its own best thermometer, one can compare changes in the thermocouple voltage to that of the sample voltage as T is varied, by using an oscilloscope to measure the time di¡erences in the response of these two voltages to a change in T . A poor thermal contact between the thermocouple and the sample can also be revealed by a change in pressure in the sample space. As the gas or air is pumped out, the thermal link between the sample and the thermocouple can change (deteriorate) and the measured thermopower would then change, due to an erroneous temperature di¡erence measurement. A large di¡erence between measurements taken under vacuum and in a gas atmosphere usually indicates poor thermal contact between sample and thermocouple. However, if only thermal conductivity is measured, heat loss due to convection (or conduction via the gas medium) could be causing the di¡erences. It is suggested that an individual’s mounting techniques

Sec. 2

STEADY-STATE METHOD (ABSOLUTE METHOD)

191

be developed for thermopower measurements to more fully understand thermal contact issues before proceeding with thermal conductivity measurements. The authors prefer using a di¡erential thermocouple for thermal conductivity measurements ; thus only two lead wires are coming o¡ of the sample to minimize conduction heat loss. Each thermocouple leg must be a low-thermal-conductivity material (Cu leads should be avoided). For faster sample throughput, it is often desirable to use a permanently mounted thermocouple and thermally anchor the sample and the thermocouple through a common medium with varnish or some other thin contacting adhesive. This has advantages but is more likely to cause a thermal anchoring problem resulting in an erroneous T reading. At low temperatures, calibration and subtraction of the lead contributions can also be a source of error ; since T is smaller, as is the signal-to-noise ratio of the thermocouple voltage. 2.2. Heat Loss Terms Heat loss due to radiation e¡ects between the surroundings and the sample, as well as convection currents or conduction through any lead wires can be substantial. The radiation loss (which can be quite large near room temperature) is given by Q ¼ "SB AðTSAM4 TSURR4 Þ;

ð3Þ

where T SAM and T SURR are the temperature of the sample and the surroundings, respectively, SB is the Stephan^Boltzmann constant SB = 5.7 108 W/m2 -K4 , and " (0 < " < 1) is the emissivity. Proper thermal shielding and thermal anchoring are essential, and a thermal heat shield that is thermally anchored to the sample heat sink is the ¢rst step. A heat shield and sample probe / base are described in detail for our apparatus at Clemson University in Ref. 11. One might also attach heaters at various points along the heat shield to allow the possibility of being able to match the gradient along the sample. Using a feedback circuit coupled with computer data acquisition and control can allow this to be automated. It is also suggested to metal (e.g., Au) plate the inside of the heat shield in order to aid its re£ectivity. Usually the upper temperature limit for measuring thermal conductivity of a sample is restricted by radiation losses. A more complete description of the issues related to high-temperature thermal conductivity measurements can be found in an extensive chapter by M. Laubitz.16 Thus, one of the disadvantages in using a standard steady-state method is that for temperatures above T 150 K, radiation loss can become a relatively serious problem and the question is how to e¡ectively deal with these losses. For relatively large samples (short and fat), radiation e¡ects are typically negligible below 200 K. In order to correct for the radiation loss at higher temperatures, one must either measure the radiation or determine an estimate for the losses. One way in which to account for the radiation correction is as follows. Once the total thermal conductivity (T Þ is measured, the Wiedemann^Franz Law (E = L0 T , where L0 is the Lorentz number, is the electrical conductivity, and T is the temperature) is used to extract the electronic contribution (E Þ to the thermal conductivity from the previously measured electrical conductivity. From this, the lattice contribution (L Þ to the thermal conductivity is then determined, where L ¼ T E . Upon inspection of the resulting plot of the lattice thermal conductivity (L Þ versus temperature, the curve most likely will exhibit a characteristic temperature dependence

192 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

above the low-temperature phonon peak, the so-called crossover temperature.17 Typically for a crystalline material, L will exhibit an inverse temperature dependence at high temperatures, L 1/T , due to phonon^phonon scattering. Other types of material may demonstrate other temperature dependence of L , such as 1/T 0:5 , or it may be independent of temperature.18 If the heat conduction and radiation losses have been minimized with the appropriate measurement system design, then radiation losses should be very small below T 150 K. Therefore, L versus T is mathematically ¢t above the low-temperature phonon peak (if one exists) to T 150 K. This ¢t is applied and the lattice thermal conductivity is extrapolated to T 300 K. Then the extrapolated L and the measured L are compared to each other, and their di¡erence is designated by L . The sample temperature is given by T + T , where T is the base temperature, or the temperature of the surroundings, T SURR (i.e., T = T SURR Þ. After a Taylor expansion of (T SAM Þ4 - (T SURR Þ4 the radiation loss is found to be proportional to T 3 as a function of the overall temperature. Thus, if L displays a temperature dependence proportional to T 3 , one can be relatively con¢dent that L is due to radiation losses. For example, the quasicrystal sample, shown in Fig. 2, displays a very characteristic shape; in this case the curve goes as 1/T from 80 K to 150 K. Above 150 K the curve deviates from this ¢t. If a curve of 1/T is plotted in conjunction with the calculated lattice and the di¡erence between the two is called L , it is observed that, near room temperature, the di¡erence in the calculated

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FIGURE 2 Plot of the thermal conductivity as a function of temperature for an AlPdMn quasicrystal. The total, lattice, and electronic contributions to the thermal conductivity are shown as closed circles, closed diamonds, and closed triangles, respectively. The E = L0 T is calculated from the WiedemannFranz relationship discussed in the text. The total, lattice, and electronic thermal conductivities are labeled, TOT , L , and E , respectively. The di¡erence between the extrapolated or corrected and measured lattice thermal conductivity, L , is plotted as a function of T 3 in the inset, illustrating losses due to radiation e¡ects.

Sec. 3

THE COMPARATIVE TECHNIQUE

193

and measured lattice thermal conductivity is on the order of 1 W m1 K1 . An inset in Fig. 2 shows L plotted as a function of T 3 , and a very linear curve is observed. Thus, L is assumed to be due to radiation loss that is proportional to T 3 and can be corrected for in the original measurements. The total thermal conductivity corrected for radiation losses can be determined by adding the calculated electronic thermal conductivity and the corrected lattice thermal conductivity together. With this iterative process a ¢rst level of corrections for radiative losses is hopefully achieved. These corrections should certainly be less than 15^20% at room temperature, otherwise better experimental design or a di¡erent sample size should be employed. It also may be necessary to change the emissivity of the sample by applying a thin coating, but this can contribute to other loss e¡ects. Heat losses can also be due to convection or circulating gas £ow around the sample. Heat convection is a more subtle e¡ect and less readily able to quantify as conduction or radiation losses. The best way to minimize these convection losses is to operate the measurement with the sample in a moderate vacuum (104 ^ 105 torr). If convection is still a problem, then possibly ba¥es can be integrated to disturb the convection currents. The other substantial heat loss mechanism is due to heat conduction. Thermal resistance of leads, heaters, etc., as well as interface anchoring between the sample, the heater, and the heat sink is important. A high vacuum will certainly reduce the heat loss due to conduction through any gaseous medium around the sample. Another source of heat conduction loss is via the thermocouple lead wires or other measurement leads attached to the sample for temperature measurement. Long lead lengths of small diameter (small A) with su⁄cient thermal anchoring (so essentially no T arises between the sample and shield) are important for minimizing this e¡ect. One must accurately determine the power through the sample by considering the various loss mechanisms. Even if one minimizes or e¡ectively measures many of these losses, the accurate determination of the sample length (LS Þ and cross-sectional area (A) can be a challenge to achieving high precision within a 5^10% uncertainty. Again, measuring known standards and thoroughly calibrating the apparatus are essential to understanding its resolution. Several standards with di¡erent values for their thermal conductivity are suggested. Pyrex and Pyroceram are suggested as low-thermalconductivity standards ( < 4^5 W m1 K1 Þ, calibrated 304 stainless steel for intermediate values ( < 20 W m1 K1 Þ, and HOPG graphite for higher values (20 < < 100 W m1 K1 Þ. The latter two can both be obtained from the National Institute of Standards and Technology.19 3. THE COMPARATIVE TECHNIQUE Other techniques may also be considered and are just as valid as the previously described absolute steady-state method. In the comparative technique a known standard is put in series between the heater and the sample. This technique, also a steady-state heat £ow technique, achieves the best results when the thermal conductivity of the standard is comparable to that of the sample. Indeed, the same types of errors and corrections must be considered as for the absolute steady-state technique. In addition, there are more sources of potential error due to thermal contact e¡ects in the comparative technique than in the absolute technique, since more thermal contact points are involved.

194 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

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Heat Sink FIGURE 3 Con¢guration for measuring of the thermal conductivity using a comparative technique, where the sample is in series with a known standard.

FIGURE 4 Con¢guration for measuring thermal conductivity using a radial £ow technique. From Slack and Glassbrenner, Thermal Conductivity of Germanium from 3 K to 1020 K, Phys. Rev. 120, No 3, (1960). This requires rather large samples but radiation losses are minimized, thus making it appropriate for high temperature.

Sec. 4

THE RADIAL FLOW METHOD

195

The power through the standard (1 Þ is equal to the power through the sample (2 Þ, and if the thermal conductivity of the standards 1 is known, then the thermal conductivity of the sample, 2 , is ð4Þ 2 ¼ 1 fA1 T1 L1 =A2 T2 L2 g: An illustration of a sample mounted for a comparative technique measurement is shown in Fig. 3. One can also add another standard on the other side of the sample (i.e., the sample is sandwiched between two known or standard materials), known as the double comparative technique. But again, more thermal contact points are added which can be potential sources of error. 4. THE RADIAL FLOW METHOD The conventional longitudinal heat £ow method can be satisfactory at low temperatures, but serious errors can occur at high temperatures due to radiative losses directly from the heater and from the sample surface. In the radial heat £ow method, heat is applied internally to the sample, generally minimizing radiative losses from the heat source. As presented by Tye,20 radial £ow methods have been applied to solids having a wide range of thermal conductivities. Since radial £ow methods are relatively more di⁄cult to apply than linear £ow methods, they are not commonly employed below room temperature. An illustration diagram of the radial £ow method is shown in Fig. 4.21 Internal sample heating has been accomplished in a variety of sample geometries, including imbedding in the sample, at the center of a hollow sample, and by direct electrical heating of the sample itself. The symmetry of the sample geometry must correspond to the geometry of the heater and permit inclusion of the heater. Chapter 4 of Tye20 gives a comprehensive review of ¢ve classes of apparatus in radial methods. Class 1. The simplest to employ is a cylindrical geometry with a central source or sink of power and assumed ‘in¢nite’ length, therefore without end guards. Class 2. Cylindrical geometry frequently consisting of stacked disks and a central source or sink but of ¢nite length, therefore having end guards. Class 3. Spherical and ellipsoidal geometry with a completely enclosed heat source, having some sample preparation di⁄culties. Class 4. Concentric cylindrical sample geometry consisting of known and unknown thermal conductivities with a central heat source or sink and analyzed by comparative methods. Class 5. Electrically self-heating samples, having cylindrical geometry where the radial temperature distribution is analyzed. In the frequently employed cylindrical symmetry, heat is generated along the axis of a cylinder. At steady-state conditions the radial temperature ¢eld is measured at two di¡erent radii. For heat £ow in a cylinder between radii r1 and r2 , assuming no signi¢cant longitudinal heat loss, thermal conductivity is found by solving Zr1 dr P ¼ ½Tr1 Tr2 = ð5Þ 2r r2

196 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

for : ¼

P lnðr2 =r1 Þ ; 2LT

ð6Þ

where P is heat energy input per unit time, L is sample length, T is the temperature di¡erence between the thermocouples, and r1 and r2 are the radial positions of the inner and outer thermocouples, respectively. Slack and Glassbrenner employed a combination of linear and radial methods to measure the thermal conductivity of germanium from 3 to 1020 K.22 This was accomplished by using di¡erent samples in two di¡erent apparatus, and then relating the two measurements in overlapping temperature ranges by correcting the lowtemperature results to match the high-temperature curve. A conventional linear method was used below 300 K and a radial method above 300 K to limit error due to radiation losses. Figure 4, taken from reference 22, illustrates the sample con¢guration for the radial £ow method. The sample size was relatively large, a 6cm-long cylinder with a 1.3-cm radius (but this is generally considered small for a radial £ow sample). The cylinder was sectioned and longitudinal grooves were cut for the central heater and thermocouples at r1 and r2 , which were cemented in place. In cylindrical geometry, according to Carslaw and Jaeger, as long as the length-to-diameter ratio is greater than 4 to 1, the end-loss error is less than 0.5%.23 Since in Eq. (5), depends on ln(r2 /r1 Þ, the measurement of r1 and r2 is less critical than the measurement of thermocouple separation in the linear geometry as shown in Fig. 1. Even so, Glassbrenner and Slack reported an improvement in the radial thermocouple location error from 20% in 1960 to 5% in 1964 by the use of alumina tubing in holes in the sample.24 More recently (1995), thermal di¡usivity was measured at high temperatures (800^1800 K) by Khedari et al: by employing a cylindrical geometry radial heat £ow apparatus and a periodic stationary method.25 In the periodic stationary method the heat source is sine modulated, creating a radial thermal sine wave through the sample. Thermal di¡usivity is calculated from the phase ratio and amplitude ratio coming from the thermocouple signals at r1 and r2 . The thermocouples were placed in axial holes in the sample. The time constants were adjusted by adjusting the experimental dimensions. The uniformity of heat £ow, the in£uence of axial heat £ow (the in¢nite cylinder assumption), the thermocouple position measurement error, and the disturbance of the thermal ¢eld around the thermocouples were all experimentally evaluated by Khedari et al:25 They found a dependency of the measurements on the frequency and a gap between the di¡usivity calculated from the phase ratio and the di¡usivity calculated from the amplitude ratio. Benigni and Rogez26 continued the work of Khedari et al:, and in 1997 they reported experimental data and a new model showing three factors acting in parallel that in£uenced the total thermocouple contact conductance, correcting much of the error reported by Khedari et al: These three factors, solid conduction at contact points, gas conduction, and radiation within the drilled hole containing a thermocouple, were found to be the main problems to be corrected to increase accuracy. Radial methods are not often used for low-temperature measurement of thermal conductivity since relatively easier longitudinal methods usually o¡er satisfactory results. In addition, the radial £ow method typically requires much larger samples

Sec. 6

THE PULSE-POWER METHOD (‘‘MALDONADO’’ TECHNIQUE)

197

than the longitudinal or linear methods, and this can be di⁄cult to achieve with high-grade research polycrystalline or single-crystal materials. The high-temperature advantage due to minimum radiative losses from the heat source is the primary reason to choose a radial method. The next several techniques will just be summarized, and it is suggested that the reader refer to the references for a more complete description. Many are not steadystate measurements but are more like quasi-linear or pulsed power heat £ow methods. Some are incorporated into commercial systems, and one should contact the companies for speci¢c details of the measurement systems. A technique that is becoming popular for thermoelectric materials, as well as for many nonconducting low-thermal-conductivity systems, is the ‘‘3-! technique.’’2;27 The 3-! technique was originally developed for measuring the thermal conductivity of glasses and other amorphous solids and is appropriate for measuring the thermal conductivity of very thin samples or thin ¢lms. It is discussed in this book. 5. LASER-FLASH DIFFUSIVITY Another technique for measuring the thermal properties of thin-¢lm and bulk samples is the laser-£ash thermal di¡usivity method.28 In this technique one face of a sample is irradiated by a short ( 1 ms) laser pulse. An IR detector monitors the temperature rise of the opposite side of the sample. The thermal di¡usivity is calculated from the temperature rise versus time pro¢le. Algorithms exist for correcting various losses typically present in this measurement. The thermal conductivity is related to the thermal di¡usivity, D = /d Cp , where d is the density, and Cp is the heat capacity. At high temperatures where the heat capacity (C P Þ is a constant, the thermal di¡usivity measurement essentially yields the thermal conductivity. Therefore, in principal, this technique can be used to measure thermal conductivity. However, the utility of this method requires fairly stringent sample preparation requirements. In order to prevent ‘‘£ash-throughs’’ to the IR detector, there is very little £exibility in the required sample geometry (typically thin disks or plates). In addition, the sample surfaces must be highly emissive to maximize the amount of thermal energy transmitted from the front surface and to maximize the signal observed by the IR detector. Usually this requires the application of a thin coating of graphite to the sample surfaces. If good adhesion is not achieved, this coating procedure can potentially be a source of signi¢cant error. Commercial units are available that allow measurement of thermal di¡usivity at temperatures from 77 K to 2300 K.29 These units are typically automated and reasonably easy to use. The thermal di¡usivity is related to thermal conductivity through the speci¢c heat and sample density ; i.e., the laser-£ash method is sometimes used to determine thermal conductivity indirectly when the speci¢c heat and density have been measured in separate experiments. However, these systems require a relatively large sample size, a 2-inch diameter disk for some systems. This can be di⁄cult to obtain for a ‘‘research sample.’’ 6. THE PULSE-POWER METHOD (‘‘MALDONADO’’ TECHNIQUE) Traditional methods for measuring thermal conductivity typically require relatively long waiting times between measurements to enable the sample to reach steady-

198 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

I(t) Current Source

R(T1) Heater Resistance C(T1) Heater Heat Capacity

K(T1-T0) Sample Thermal Conductance

Bath T0 FIGURE 5 Schematic for ‘‘Maldonado’’ technique as described in Ref. 5.

FIGURE 6 Temperature rise and fall for pulsed power for measuring of thermal conductivity using the ‘‘Maldonado’’ technique. From Ref. 5. The time dependence of the temperature di¡erence across the sample is showing where () represents a simulation and (o) represents experimental data.

Sec. 7

THE PULSE-POWER METHOD (‘‘MALDONADO’’ TECHNIQUE)

199

state considerations. These time delays may allow various o¡set drifts to in£uence the measurement. With the pulse-power method described here, the bath temperature is slowly drifted, while the heater current that generates the thermal gradient is pulsed with a square wave.5 Maldonado applied this technique in 1992 for the simultaneous measurement of heat conductivity and thermoelectric power.5 A diagram of the sample setup is shown in Fig. 5. Here we describe only the application to the measurement of thermal conductivity. Since thermal equilibrium is never established, time between measurements can be signi¢cantly reduced, facilitating higher-measurement resolution. The experimental setup is basically the same as in steady-state measurements except that the heating current is pulsed with a square wave of constant current, thereby creating small thermal gradients. Figure 6 shows the response of the sample to the pulsed power with the ‘‘Maldonado’’ method. The experimental setup is basically the same as in steady-state measurements except that the heating current is pulsed with a square wave of constant-amplitude current, thereby creating small thermal gradients. No steady-state thermal gradient is established or measured. The heat balance equation for the heater in Fig. 5 is written as the sum of the current dissipated in the heater and the heat conducted by the sample: dQ dT1 ¼ CðT1 Þ ¼ RðT1 ÞI 2 ðtÞ KðT1 T0 Þ: ð7Þ dt dt In Fig. 5, dQ/dT is the time rate of change of heat in the heater, T1 is the heater temperature, C is the heater heat capacity, R is the heater resistance, and K is the sample thermal conductance. Since K is a function of temperature, the temperature di¡erence, T1 ^ T0 is kept small with respect to the mean sample temperature so that K is considered as a function of mean sample temperature. The bath temperature T0 is allowed to drift slowly and a periodic square-wave current with period 2 is applied through the resistance heater, which causes T1 to vary with period 2. Maldonado arrives at a solution of Eq. (1) by including several simpli¢cations. Since, CðT Þ, RðT Þ, and KðT Þ are smooth functions of T , then T0 is used instead of T1 as the argument of C, R, and K. In addition, an adiabatic approximation is employed by considering T0 as nearly constant, since the temperature drift is slow compared to the periodic current. The solution has a sawtooth form as shown in Maldonado’s ¢gure (Fig. 6). The di¡erence between the smooth curves through the maxima and minima yields a relation for thermal conductance : RI02 K K¼ tanh : ð8Þ Tpp 2C The overall accuracy is reported by Maldonado to be better than 5%, with the principal error sources being T measurement and, of course, sample geometry measurement for calculation of thermal conductivity from the thermal conductance. An advantage of this method is that the sample temperature is slowly slewed while the measurement is performed and can save time in the measurement sequence since achieving a steady-state is not necessary. This technique has recently been employed in a commercial device sold by Quantum Design Corporation.30

200 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

7. PARALLEL THERMAL CONDUCTANCE TECHNIQUE Thermal conductivity measurements on relatively small samples are an additional, yet very important, challenge for the scienti¢c community. For several reasons, including size dependence e¡ects or, perhaps, natural size limitations, it is important to be able to measure these smaller samples. In order to measure the thermal conductivity of small needlelike single-crystal samples (2.0 0.05 0.1 mm3 Þ; such as pentatellurides and single-carbon ¢bers, a new technique called parallel thermal conductance (PTC) was recently developed.6 A thermal potentiometer measurement method had been developed previous to the PTC technique by Piraux, Issi, and Coopmans to evaluate the thermal conductivity of thin carbon ¢bers.31 However, the measurement was quite laborious and tedious. In the more typical steady-state method for measuring thermal conductivity, thermocouples are attached to the sample to measure the temperature gradient and a heater is included to supply the gradient. However, attaching thermocouples and heaters to small samples essentially minimizes the necessary sensitivity needed to perform these measurements. Thus, the measurement of the thermal conductivity of small samples and thin ¢lms has been a formidable challenge, with few successes, due to heat loss and radiation e¡ects. It is also di⁄cult for the small samples to support the heaters and thermocouples without causing damage to the sample. In essence, the PTC technique is a variation of a steady-state technique (P vs. T ), which is adapted to measure the thermal conductivity of these types of samples as described in the following. Due to the inability of a sample of this size to support a heater and a thermocouple, a sample holder or stage had to been developed. Figure 7 illustrates the mounting and setup for the PTC technique. This technique requires that the thermal conductance of the sample holder itself must be measured ¢rst, which determines the base line or background thermal conduction and losses associated with the sample stage. The second step consists of attach-

FIGURE 7 Sample con¢guration and mount for measuring thermal conductivity using the PTC technique.

Sec. 8

Z-METERS OR HARMAN TECHNIQUE

201

ing the sample and measuring the new thermal conductance of the system. By subtraction, PTC is calculated. This conductance is due to the sample, thermal contacts and blackbody radiation from the sample. The contributions of heater and thermocouple lead wires and radiation e¡ects of the holder have been subtracted. Of course, one of the necessary components of this technique is the reproducibility of the thermal conductance of the holder as a function of time and temperature, as well as being able to achieve a very low overall thermal conductance of the holder. The results from this technique enabled the measurement of several small samples that could not be measured by other techniques.32 However, accurate determination of sample dimensions can be a limiting factor in determining absolute thermal conductivity values. 8. Z-METERS OR HARMAN TECHNIQUE Another widely used technique for characterizing thermoelectric materials is the ‘‘Harman Technique’’ or Z-meter.3336 This is a direct method for obtaining the ¢gure of merit, ZT , of a material or a device. Consider the voltage as a function of time for a thermoelectric material under various conditions. If there is no T and I = 0, then V S = 0, where V S is the sample voltage. A current, I, is applied, and the voltage increases by IRS , where RS is the sample resistance, to the value V IR . Recall that when a current is applied to a thermoelectric material a temperature gradient, T , arises from the Peltier e¡ect (QP ¼ IT ) and a voltage, V T E , will add to the IRS voltage. Under steady-state or adiabatic conditions, the heat pumped by the Peltier e¡ect will be equal to heat carried by the thermal conduction; IT ¼ AT =L:

ð9Þ

One can derive a relationship between ZT and the adiabatic voltage (VA = VIR + 51;52 VT E Þ and the IR sample voltage, VIR ZT ¼ VA =VIR 1 ¼ 2 T =;

ð10Þ

where is the measured electrical resistivity of the sample. This relationship is a reasonable approximation to ZT but assumes ideal conditions unless corrections are accounted for, such as contacts, radiation e¡ects, and losses. The ¢rst criterion is that the sample typically needs to possess a ZT 0.1. Also, contact e¡ects, sample heating from the contacts and the sample resistance, should be negligible, and T e¡ects from contact resistance di¡erences can also be negligible. The thermal conductivity can be estimated from the Harman technique in two ways: ¢rst measure R and , then ZT from Eq. (8), and the thermal conductivity can then be determined. Another way is to use Eq. (9) in the form I ¼ ðA=T LÞT : ð11Þ Then at a constant temperature, the following relationship holds, where I ¼ (A=T L) T = C 0 T , where C 0 is a constant at a given T . Thus, the linear part of the slope of an I T plot will yield the thermal conductivity. The ZT determined from the Harman method is essentially an ‘‘e¡ective ZT ,’’ or, in other words, the operating ¢gure of merit of the device. This technique requires that essentially no contact resistance e¡ects exist (recall I 2 fRC1 - RC2 g = P C T across the sample from I 2 R heating). Information from this technique should be

202 Chap. 2.1 CONDUCTIVITY

MEASUREMENT TECHNIQUES FOR DETERMINING THERMAL

compared to the measurements of the individual parameters that go into ZT . It should not be a substitute for knowing the parameters. 9. SUMMARY In summary, several methods have been presented and discussed for the experimental determination of the thermal conductivity of a bulk solid-state material. Much care must be taken in the experimental design of the apparatus and the evaluation of the resulting data. Issues relating to understanding loss terms such as radiation or heat conduction were discussed along with issues related to appropriate heat sinking of the sample and corresponding measurement lead wires. Several techniques were discussed and one must then determine which technique is most appropriate for the speci¢c sample geometry and the speci¢c measurement equipment and apparatus available. However, the determination of the thermal conductivity of a material to within less than 5% uncertainty may be quite formidable, and most often a serious limiting factor may be the accurate determination of the overall sample dimensions. 10. REFERENCES 1.

2. 3.

4. 5. 6.

7. 8. 9. 10. 11. 12. 13.

14.

See, for example, Thermal Conductivity of Solids, J. E. Parrott and A. D. Stuckes (Pion Limited Press, 1975), T. C. Harman and J. M. Honig, Thermoelectric and Thermomagnetic E¡ects and Applications (McGraw-Hill, New York, 1967). D. G. Cahill, Thermal Conductivity Measurement from 30 to 750 K: The 3! Method Rev. Sci. Instrum. 61, 802 (2001). See, for example, S. E. Gustafsson and E. Karawacki, Transient hot-strip probe for measuring thermal properties of insulating solids and liquids Rev. Sci. Instrum. 54, 744 (1983) and references therein. T. Borca-Tasciuc and Gang Chen Experimental Techniques for Thin Film Thermal Conductivity Characterization Chapter 2.2 of this book. O. Maldonado Pulse Method for Simultaneous Measurement of Electric Thermopower and Heat Conductivity at Low Temperatures Cryogenics 32, 908 (1992). B. M. Zawilski, R. T. Littleton IV, and Terry M. Tritt Description of the Parallel Thermal Conductance Technique for the Measurement of the Thermal Conductivity of Small Diameter Samples Rev. Sci. Instrum. 72, 1770 (2001). G. A. Slack, Solid State Physics (Academic Press, New York, 1979). R. P. Tye, ed. Thermal Conductivity Vol. I and Vol. II Academic Press, New York, 1969. R. Berman, Thermal Conduction in Solids Clarendon Press, Oxford, 1976. Methods of Experimental Physics: Solid State Physics, Vol. 6, editor: L. Marton, Academic Press, New York, 1959. Amy L. Pope, B. M. Zawilski, and Terry M. Tritt Thermal Conductivity Measurements on Removable Sample Mounts Cryogenics 41, 725 (2001) J. Kopp and G. A. Slack Thermal Contact Problems in Low Temperature Thermocouple Thermometry Cryogenics, p 22, Feb. 1971. See for example (a.) Thermoelectric Materials: Structure, Properties and Applications. Terry M. Tritt Encyclopedia of Materials: Science and Technology, Volume 10, pp 1-11, K. H. J. Buschow, R. W. Cahn, M. C. Flemings, B. Ilschner, E. J. Kramer, S. Mahajan, (eds) Elsevier Press LTD, Oxford, Major Reference Works, London, UK (b) Thermoelectrics : Basic Principles and New Materials Developments, G. S. Nolas, J. Sharp and H. J. Goldsmid, Springer Series in Materials Science Volume 45, 2002. Terry M. Tritt Measurement and Characterization of Thermoelectric Materials T. M. Tritt, M. Kanatzidis, G. Mahan and H. B. Lyons Jr. (Editors), 1997 Materials Research Society Symposium Proceedings Volume 478: Thermoelectric Materials, New Directions and Approaches p 25, 1997.

Sec. 10

REFERENCES

203

15. C. Uher Thermoelectric Property Measurements Naval Research Reviews, Thermoelectric Materials, Vol. XLVIII, p 44, 1996. 16. M. J. Laubitz in Thermal Conductivity edited by R. P. Tye, vol. 1, Chap. 3 (Academic Press, London; 1969), p. 111. 17. The crossover temperature of the low temperature phonon peak is the peak or ‘‘hump’’ in the thermal conductivity where there is a gradual change in the dominant scattering e¡ect, such as from phononsphonon interactions at high temperatures to boundary scattering at low temperatures. See for example: Figure 3.1, R. Berman, Thermal Conduction in Solids, Oxford University Press, (1976) New York 18. P. G. Klemens Chapter 1, p.1 Thermal Conductivity Vol.1, edited by R. P. Tye, Academic Press, New York, 1969. 19. NIST website: http://www.nist.gov 20. Chapter 4 (1969) Thermal Conductivity Vol. I and Vol. II, edited by R. P. Tye Academic Press, New York, 1969. 21. Chapter 1, pg. 186, Fig. 1, 1969 Thermal Conductivity Vol. I and Vol. II edited by R. P. Tye, Academic Press, New York, 1969. 22. Glen A. Slack, and C. Glassbrenner Thermal Conductivity of Germanium from 3K to 1020K, Physical Review, Volume 120, No 3, Nov 1, 1960. 23. H. S. Carslaw and J. C. Jaeger Conduction of Heat in Solids Oxford University Press, Oxford, 1959. 24. C. J. Glassbrenner and Glen A. Slack Thermal Conductivity of Silicon and Germanium from 3o K to the Melting Point Physical Review, V 134, N 4A, 18 May 1964. 25. J. Khedari, P. Benigni, J. Rogez, and J. C. Mathieu New Apparatus for Thermal Di¡usivity Measurements of Refractory Solid Materials by the Periodic Stationary Method Rev. Sci. Instrum. 66 (1), January, 1995. 26. P. Benigni and J. Rogez High Temperature Thermal Di¡usivity Measurement by the Periodic Cylindrical Method: The problem of Contact Thermocouple Thermometry, Rev. Sci. Instrum. 68 (3), July, 1997. 27. David Cahill, Henry E. Fischer, Tom Klitsner, E. T. Swartz, and R. O. Pohl Thermal Conductivity of Thin Films: Measurements and Understanding J. Vac. Sci. Technol. A, 7, 1260, 1989. 28. F. I. Chu, R. E. Taylor and A. B. Donaldson, Thermal di¡usivity measurements at high temperatures by a £ash method Jour. of Appl. Phys. 51, 336, 1980. 29. See for example: (a) A. B. Donaldson and R. E. Taylor Thermal di¡usivity measurement by a radial heat £ow method J. Appl. Phys. 46, 4584, 1975. J. W. Vandersande and R. O. Pohl Simple Apparatus for the Measurement of Thermal Di¡usivity between 80-500 K using the Modi¢ed Angstrom Method, Rev. Sci. Instrum. 51, 1694, 1980. J. Gembarovic and R. E. Taylor A New Data Reduction Procedure in the Flash Method of Measuring Thermal Di¡usivity Rev. Sci. Instrum 65, 3535, 1994. 30. Thermal Transport Option for the Physical property Measurement system, Quantum Design Corp, San Diego CA. See also Physical Properties Measurement System: Hardware and Operation Manual. 31. L. Piraux, J.-P. Issi, and P. Coopmans Measurement 52, (1987). 32. B. M. Zawilski, R. T. Littleton IV, and Terry T. Tritt Investigation of the Thermal Conductivity of the Mixed Pentatellurides Hf1 X ZrX Te5 , Appl. Phys. Lett. 77, 2319 (2000). 33. T. C. Harman Special Techniques for Measurement of Thermoelectric Properties. J. Appl. Phys. 30, 1373, 1959. 34. T. C. Harman, J. H. Cahn and M. J. Logan Measurement of Thermal Conductivity by Utilization of the Peltier E¡ect J. Appl. Phys. 30, 1351, 1959. 35. A. W. Penn The Corrections Used in the Adiabatic Measurement of Thermal Conductivity using the Peltier E¡ect. J. Sci. Instrum. 41, 626, 1964. 36. A. E. Bowley, L. E. J. Cowles, G. J. Williams, and H. J. Goldsmid Measurementof the Figure of Merit of a Thermoelectric Material J. Sci. Instrum. 38, 433, 1961.

Chapter 2.2

EXPERIMENTAL TECHNIQUES FOR THINFILM THERMAL CONDUCTIVITY CHARACTERIZATION T. Borca-Tasciuc Department of Mechanical, Aerospace and Nuclear Engineering Rensselaer Polytechnic Institute Troy, NY, USA

G. Chen Mechanical Engineering Department, Massachusetts Institute of Technology, Cambridge, MA, USA

1. INTRODUCTION Knowledge of the thermal conductivity of thin ¢lms and multilayer thin-¢lm structures is critical for a wide range of applications in microelectronics, photonics, microelectromechanical systems, and thermoelectrics.1 4 The last 20 years have seen signi¢cant developments in thin-¢lm thermal conductivity measurement techniques.5 8 Despite these advances, the characterization of the thermal conductivity of thin ¢lms remains a challenging task. Direct measurements of the thermal conductivity, for example, typically require the determination of the heat £ux and the temperature drop between two points of the sample. Figure 1 shows a typical thin¢lm sample con¢guration and the experimental challenges associated with the thermal transport characterization of a thin-¢lm-on-substrate system. Often, the thermal conductivity of thin ¢lms is anisotropic, as with polycrystalline thin ¢lms with columnar grains9 or superlattices made of periodic alternating thin layers. The determination of the thermal conductivity in di¡erent directions (e.g., the crossplane direction, which is perpendicular to the ¢lm plane, or the in-plane direction which is parallel to the ¢lm plane) encounters di¡erent challenges. For obtaining

206 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

Sample configuration and characterization challenges Cross-Plane (⊥ ⊥) Small ∆T⊥

Tinterface=?

Heat Source

In-Plane (||) Thin Anisotropic Film k⊥≠k|| Large Heat Leakage || Lea

Substrate

FIGURE 1 Typical sample con¢guration and challenges raised by the thermal conductivity characterization of thin ¢lms. Because the ¢lm typically has anisotropic thermal properties, measurements must be carried out in both the cross-plane and in-plane directions. For the cross-plane direction the di⁄culties consist of creating a reasonable temperature drop across the ¢lm without creating a large temperature rise in the substrate and experimentally determining the temperature drop across the ¢lm. The in-plane thermal conductivity measurement is a¡ected by heat leakage through the substrate, which makes it di⁄cult to determine the actual heat £ow in the plane of the ¢lm.

the cross-plane thermal conductivity, the experiment typically requires ¢nding out the temperature drop across the ¢lm thickness, which ranges from nanometers to microns. The di⁄culties consist of (1) creating a reasonable temperature drop across the ¢lm without creating a large temperature rise in the substrate, and (2) experimentally measuring the temperature drop across the ¢lm. On the other hand, the in-plane thermal conductivity measurement may look easier because temperature sensors can be placed along di¡erent locations on the ¢lm surface. However, heat leakage through the substrate makes it di⁄cult to determine the actual heat £ow in the plane of the ¢lm. To overcome these di⁄culties, di¡erent strategies have been developed to measure the thin-¢lm thermal conductivity, or thermal di¡usivity, in di¡erent directions. These strategies are shown schematically in Fig. 2. In the cross-plane direction, the general strategies involve (1) creating a large heat £ux through the ¢lm while minimizing the heat £ux in the substrate and (2) measuring the surface temperature rather than the temperature drop. These can be realized by, for example, using microfabricated heaters directly deposited on the ¢lm. Furthermore, by using a small heater width, the heat £ux going through the ¢lm is large, while the heat spreading inside the substrate signi¢cantly reduces the temperature drop in the substrate. Another technique is to use transient or modulated heating that limits the heat-a¡ected region to small volumes within the ¢lm or its immediate surroundings. As for the in-plane direction, one often-used strategy is to remove the substrate, such that the heat £ux through the ¢lm can be uniquely determined, or to deposit the ¢lms on thin, low-thermal-conductivity substrates, which minimizes heat leakage. Other methods have also been developed that take advantage of lateral heat spreading surrounding small heat sources. In the following sections, di¡erent methods for thin-¢lm thermophysical property measurements are presented. The techniques are categorized based on di¡erent heating and temperature sensing methods : electrical heating and sensing based

Sec. 1

INTRODUCTION

207

Thermal characterization strategies Cross-Plane (⊥ ⊥)

In-Plane (||) Freestanding

Modulation/Pulse Heating

Micro-Heat source & T sensor

Thin,low k substrate.

Substrate

Substrate

Spreading with narrow heater or burried insulation

FIGURE 2 Strategies developed to measure the thin-¢lm thermal conductivity, or thermal di¡usivity, in di¡erent directions. In the cross-plane direction, the general strategies are creating a large heat £ux through the ¢lm while minimizing the heat £ux in the substrate and measuring the surface temperature rather than the temperature drop. For the in-plane direction, often-used strategies are to remove the substrate such that the heat £ux through the ¢lm can be uniquely determined or to deposit the ¢lms on thin, low-thermal-conductivity substrates, which minimizes heat leakages. Other methods take advantage of the lateral heat spreading that surrounds small heat sources.

TABLE 1. Summary of Thin-Film Thermophysical Properties Characterization Techniques

Thin-FilmThermophysical CharacterizationTechniques

Electrical 3ω 2strips3ω

Opticalheating ⊥

|| ⊥

2sensorsteady ||

Timedomain -photoreflectance -transientgrating

⊥ ACcalorimetry ||

Frequencydomain -photoreflectance

Membrane

|| -emission

Bridge

||

-displacement -deflection

Spreader

Hybrid

|| Photo-acoustic

|| ⊥ ⊥ ⊥

|| ⊥

Photo-thermoelectric || ⊥ Electro-reflectance

⊥

|| ⊥ ⊥ Electro-emission

⊥

The techniques are categorized based on di¡erent heating and temperature sensing methods: electrical heating and sensing, optical heating, and combined electrical/optical methods. The symbols on the right of each method indicate the direction [in-plane (jjÞ, cross-plane (?Þ, or both] along which the thermophysical properties characterization is performed.

208 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

on microheaters and sensors, optical heating and sensing methods, and combined electrical/optical methods. The methods presented in this chapter and their range of applications are summarized in Table 1. Representative methods in each category are selected for a more detailed discussion. Complementary information on thermophysical property characterization methods can also be found in several other review papers.5 8 2. ELECTRICAL HEATING AND SENSING The thin-¢lm thermal conductivity characterization methods presented in this section use electrical heating and sensing techniques. Some of the methods to be discussed employ the heaters also as temperature sensors, while in other techniques separate heaters and temperature sensors are used. Moreover, some of the techniques use the ¢lm itself as a heater and a temperature sensor. The advantages of electrical heating and sensing methods, compared to optical heating and sensing techniques later discussed, are that the amount of heat transfer into the sample can be controlled precisely and the temperature rise accurately determined. Such information makes it easier to obtain the thermal conductivity directly. Many of the techniques discussed employ microheaters and microsensors because high heat £uxes can be created and temperature rises can be pinpointed at micron scales. In the following discussion, the content is further divided into the cross-plane and the in-plane thermal conductivity measurements. 2.1. Cross-Plane Thermal Conductivity Measurements of Thin Films Experimentally measuring the temperature drop across a ¢lm thickness that may be as small as a few nanometers makes the cross-plane thermal conductivity characterization of thin ¢lms a challenging task. Direct probing of the temperature at the ¢lm^substrate interface by electrical sensing is typically hard to achieve without the removal of the substrate, unless the sensors are fabricated before the deposition of the ¢lm. If the latter approach is taken, one must ensure that the ¢lms deposited on the temperature sensors have similar microstructures to the ones used in reality and that the sensors used are compatible to the fabrication processes. Some measurements on spin-on polymers adopt this approach,10 but for most applications embedding temperature sensors underneath the ¢lm is not practical. Consequently, several methods have been developed to infer the temperature drop across the ¢lm. These techniques will be presented in the remainder of this section. 2.1.1. The 3! method A widely implemented approach for measuring the cross-plane thermal conductivity of thin ¢lms is the 3! method.11 Although initially developed for measuring the thermal conductivity of bulk materials, the method was later extended to the thermal characterization of thin ¢lms down to 20 nm thick.11 19 Moreover, the 3! technique was recently adapted for measurement of the in-plane and cross-plane thermal conductivity of anisotropic ¢lms and freestanding membranes.20 22 This technique is currently one of the most popular methods for thin-¢lm cross-plane thermal conductivity characterization; therefore it is discussed in more detail. In the 3! method a thin metallic strip is deposited onto the sample surface to act

Sec. 2

ELECTRICAL HEATING AND SENSING

209

1ω ω

HEATING WIRE

V3ωω

V3ωω~ T2ωω

2b

SUBSTRATE

FIGURE 3. (a) cross-sectional view and (b) top view of the heater/temperature sensor deposited on the ¢lm on substrate sample in the 3! method.

as both a heater and a temperature sensor as shown in Fig. 3. An AC current, IðtÞ ¼ I0 cosð!tÞ;

ð1Þ

with angular modulation frequency (!Þ and amplitude I 0 passing through the strip, generates a heating source with power 8 2 9 9 8 2 I0 Rh > I0 Rh cosð2!tÞ> > > 2 2 > > > > P ðtÞ ¼ I0 Rh cos ð!tÞ ¼ : ð2Þ ; þ: ; ; 2 2 DC 2! where Rh is the resistance of the strip under the experimental conditions. Therefore, the corresponding temperature rise in the sample is also a superposition of a DC component and a 2! modulated AC component: T ðtÞ ¼ TDC þ T2! cosð2!t þ ’Þ;

ð3Þ

where T2! is the amplitude of the AC temperature rise and ’ is the phase shift induced by the thermal mass of the system. If the resistance of the heater depends linearly on temperature, there is also a 2! variation in the resistance of the heater: Rh ðtÞ ¼ R0 f1 þ Crt ½TDC þ T2! cosð2!t þ ’Þg ¼ R0 ð1 þ Crt T DC ÞDC þðR0 Crt T2! cosð2!t þ ’ÞÞ2! ;

ð4Þ

where Crt is the temperature coe⁄cient of resistance (TCR) for the metallic heater and R0 is the heater resistance under no heating conditions. The voltage drop across the strip can be calculated by multiplying the current [Eq. (1)] and the resistance [Eq. (4)]: V ðtÞ ¼ IðtÞRh ðtÞ ¼ ½I0 R0 ð1 þ Crt TDC Þ cosð!tÞpower source 8 9 I R C T : 0 0 rt 2! cosð3!t þ ’Þ> ; þ> 2 3!

8 9 I R C T : 0 0 rt 2! cosð!t þ ’Þ> ; þ> 2 mod 1!

mod

: ð5Þ

This expression contains the voltage drop at the 1! frequency based on the DC resistance of the heater and two new components proportional to the amplitude of the temperature rise in the heater, modulated respectively at 1! and 3! frequencies. The 3! voltage component is detectable by a lock-in ampli¢er and is used to measure the temperature amplitude of the heater: 2V3! 2V3! T2! ¼ ’ ; ð6Þ I0 R0 Crt Crt V1!

210 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

where V 1! is the amplitude of the voltage applied across the heater. The frequencydependent temperature rise of the heater is obtained by varying the modulation frequency of the current at a constant applied voltage V 1! . One challenge of the 3! technique is measuring the small 3! signals, which are usually about three orders of magnitude smaller than the amplitude of the applied voltage. Typically, cancellation techniques are employed to remove the large 1! voltage component before measuring the 3! signal.11 The heat conduction model used to obtain the substrate and the thin-¢lm thermal conductivities is of crucial importance to the accuracy of the thermal conductivity determination. A simpli¢ed model using a line source approximation for the heater, one-dimensional frequency-independent heat conduction across the thin ¢lm, and two-dimensional heat transport in a semi-in¢nite substrate, is often used in the data analysis.12 Under these assumptions the temperature amplitude of the heater can be written as p dF TSþF ¼ TS þ ; ð7Þ 2 b w kF where b is the half-width of the heater, p=w is the power amplitude dissipated per unit length of the heater, dF is the ¢lm thickness, kF is the cross-plane thermal conductivity of the ¢lm, and T S is the temperature rise at the ¢lm^substrate interface. The heater measures only the temperature rise on the top surface of the sample (T SþF Þ which includes the temperature drops across the ¢lm and substrate. To determine the thermal conductivity of the ¢lm, one must know the temperature at the interface between the ¢lm and the substrate (T S Þ. This can be determined by either of two approaches. One approach is to calculate the temperature rise at the ¢lm^substrate interface. From the line source approximation the temperature amplitude of the heater on a bare semi-in¢nite substrate is12;23 9 8 p S p > p ; ¼ : TS ¼ 0:5 ln 2 0:5 lnð2!Þ þ i > f linear ðln !Þ; w kS 4 w kS w kS b ð8Þ where S is the thermal di¡usivity of the substrate, is a constant 1,12 and f linear is a linear function of ln !. Combining Eq., (7) and (8), it becomes clear that the substrate thermal conductivity can be determined from the slope of the real part of the experimental signal as a function of ln(!Þ. We will call this method the slope method. A di¡erent way to estimate the temperature drop across a thin ¢lm is to infer it experimentally. The di¡erential technique23 measures the di¡erence of the top surface temperature rise between the sample and a reference without the ¢lm or an identically structured ¢lm of lesser thickness. Figure 4 shows the method schematic and examples24 of the temperature rise measured by 2-m- and 30-m-width heaters deposited onto the specimen (T F Þ and reference sample (T R Þ. The sample is a 1.075-m Ge quantum-dot superlattice ¢lm deposited on the Si substrate with an intermediate 50 nm Si bu¡er layer. The electrical insulation between the heater and the ¢lm is provided by an 100 nm Six Ny layer. Although Eq. (7) and Eq. (8) are often used in data analysis, one must bear in mind that these are approximations and have limitations. A more detailed, twodimensional heat conduction model has been developed and used to analyze the

Sec. 2

ELECTRICAL HEATING AND SENSING

Reference

211

TF Sample

TR

Film of interest

Substrate

Substrate

TEMPERATURE RISE (K)

2.5 LINE-FITTING DOTS-EXPERIMENTAL

TF 2.0

∆ T=1.007K

1.5

TR

2 µ m HEATER P=27.8mW

1.0

0.50

TF

∆ T=0.093K

30 µ m HEATER P=26.5m W

TR

0.0 500

1000

1500 2000 FREQUENCY (Hz)

2500

3000

FIGURE 4. Example of an experimentally determined temperature drop across a Ge quantum-dot superlattice ¢lm using a di¡erential 3! method. In this method similar heaters are deposited on the sample and a reference without the ¢lm of interest. The temperature drop across the ¢lm is given by the di¡erence in the temperature rise of similar heaters under similar power dissipation conditions. If the experiment is performed using a pair of large-width or narrow-width heaters, the anisotropic properties of the ¢lm may be determined. The solid lines are calculated by using Eq. (9) and the ¢tted thermophysical properties of the sample.

validity of these simpli¢cations.23 Some of the ¢ndings are discussed later in the context of an anisotropic ¢lm deposited on an isotropic substrate. The model indicates that for the line source approximation [Eq.p(8)] ﬃﬃﬃﬃﬃ to be valid (within 1% error), the thermal penetration depth in the substrate 2!S must be at least 5 times larger than the heater half-width. Also, for the semi-in¢nite substrate approximation required by Eq. (8) to be valid (within 1% error), the thermal penetration depth is at least 5 times smaller than the substrate thickness. Since these conditions put opposite requirements on the frequency range of the measurement, it implies that if the ratio between the substrate thickness and heater half-width is less than 25, it is not possible to simultaneously minimize the substrate e¡ects and still satisfy the line source approximation within 1% error. In addition to these considerations, the speci¢c heat of the heater and the ¢lm, the thermal resistance of the ¢lm, and the thermal boundary resistance between the ¢lm and the substrate also a¡ect the accuracy of Eq. (8) and, consequently, the substrate thermal conductivity determination using the slope method, which is explained in a later section.

212 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

The approximation of steady-state one-dimensional heat conduction across the thin ¢lm [i.e., Eq. (7)] requires that the substrate thermal conductivity be much higher than that of the ¢lm. This is easily understood from the limiting case of a semi-in¢nite substrate deposited with a ¢lm of identical material as the substrate. In this situation the temperature sensor on the surface measures the same temperature as without the ¢lm, and, correspondingly, the temperature drop across the ¢lm is zero (neglecting thermal boundary resistance). Furthermore, Eq. (7) is based on one-dimensional heat conduction across the thin ¢lm and requires minimization of the heat spreading e¡ects inside the ¢lm, which depends on the ¢lm thermal conductivity anisotropy K F xy (ratio between the in-plane and cross-plane thermal conductivities) and the aspect ratio between heater width 2.6 and ¢lm thickness thermal conductivity is much smaller than dF . For example, if the cross-plane ¢lm pﬃﬃﬃﬃﬃﬃﬃﬃﬃ the substrate thermal conductivity and kF xy dbF <10, the heat spreading e¡ect could be accounted for by the one-dimensional heat conduction p model ﬃﬃﬃﬃﬃﬃﬃﬃﬃ if the width of the heater is replaced by a ‘‘corrected’’ width of 2b + 0.76dF kF xy . In situations where such conditions do not hold, the general expression for the heater temperature rise on a multilayer ¢lm^on^¢nite substrate system with anisotropic thermophysical properties must be used. Neglecting the contributions from the heat capacity of the heater and thermal boundary resistances, the complex temperature amplitude of a heater dissipating p=w W/m peak electrical power per unit length is23;25 Z1 p 1 sin2 ðb Þ T ¼ d; ð9Þ w ky 1 A1 B1 b2 2 0

where Ai1 ¼

Ai 1

kyi Bi kyi1 Bi1 k Bi Ai ky yi Bi1 i1

tanhð’i1 Þ tanhð’i1 Þ

; i ¼ from 2 to 12

ð10Þ

91=2 8 i2!> > 2 > k þ Bi ¼ > ; ; : xy i y i

ð11Þ

’i ¼ Bi di kxy ¼ kx =ky :

ð12Þ

In these expressions, n is the total number of layers including the substrate, subscript i corresponds to the ith layer starting from the top, subscript y corresponds to the direction perpendicular to the ¢lm/substrate interface (cross-plane), b is the heater half-width, ky and kx are respectively the cross-plane and the in-plane thermal conductivity of the layer, ! is the angular modulation frequency of the electrical current, d is the layer thickness, and is the thermal di¡usivity. If the substrate layer (i = n), is semi-in¢nite, An = -1. When the substrate has a ¢nite thickness, the value of An depends on the boundary condition at the bottom surface of the substrate : An =-tanh(Bn dn Þ for an adiabatic boundary condition or An = -1/tanh(Bn dn Þ if the isothermal boundary condition is more appropriate. The above analytical expressions do not include the e¡ects of the thermal boundary resistance between the heater and the ¢lm and the heat capacity of the heater. For a heater of thickness dh and heat capacity (c)h , with thermal boundary re-

Sec. 2

ELECTRICAL HEATING AND SENSING

213

sistance Rth between the heater and the ¢rst ¢lm, and neglecting heat conduction e¡ects inside the heater, the complex temperature rise of the heater becomes23 T þ Rth p=2bw Th ¼ ; ð13Þ 1 þ ðcÞh dh i2!ðRth þ T 2bw=pÞ where T is the average complex temperature rise determined from Eq. (9) for a multilayer-¢lm-on-substrate structure under the same heating power with zero heater heat capacity and zero thermal boundary resistance. The thermal boundary resistance, and equivalently, the ¢lm heat capacity and thermal resistance, impacts the determination of the substrate thermal conductivity when using the slope method [based on the simple expression in Eq. (7) and Eq. (8)]. Indeed, experimental results of SiO2 ¢lms on silicon substrates show that the substrate thermal conductivities determined from the slope method are smaller than standard values,15 and this trend is attributed to the e¡ect of the additional thermal resistance of the SiO2 ¢lm.23 The 3! technique employs modulation of the heat source, which brings several advantages. One is that the AC temperature ¢eld can be controlled by the modulation frequency. Choosing a reasonably high modulation frequency range, the AC temperature ¢eld is con¢ned to the region close to the heater such that the substrate can be treated as semi-in¢nite. This approach avoids the in£uence of the boundary condition at the substrate side. Another advantage of the modulation technique is that the AC signal is less sensitive to the radiation heat loss compared to DC measurement methods. The AC modulation also leads to the possibility of determining the substrate properties in addition to the ¢lm properties. Moreover, by performing the measurements over a wide frequency range it is possible to determine both the thermal conductivity and volumetric heat capacity of thin ¢lms.26 The thermal conductivity measurement is performed at relatively low frequencies, where the temperature drop across the ¢lm is frequency independent. On the other hand, at adequately high frequencies, the heat-a¡ected region can e¡ectively be con¢ned into the ¢lm, in which case the temperature drop across the ¢lm becomes sensitive also to the volumetric heat capacity of the ¢lm. 2.1.2. Steady-State Method A steady-state method has also been employed to determine the cross-plane thermal conductivity of dielectric ¢lms and the thermal boundary resistance between a microfabricated heater/thermometer and the substrate.27;28 In the 3! technique just one metallic strip acts as both the heater and the temperature sensor, whereas in the steady-state method at least two, and sometimes three, strips are deposited onto the ¢lm. One of the strips has a large width and serves as the heater and the thermometer for the temperature rise of the ¢lm surface. A second thermometer is situated in the vicinity of the heating strip and provides the temperature rise of the substrate at a known distance away from the heater. One can use a two-dimensional heat conduction model and a known thermal conductivity of the substrate, to infer the temperature rise of the substrate at the heater location from the temperature rise of the second thermometer. If the substrate thermal conductivity is unknown, a third thermometer situated at a di¡erent position away from the heater can be used to determine the substrate thermal conductivity. Typically the di¡erence between the temperature of the second thermometer and the temperature of

214 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

the substrate underneath the ¢rst thermometer is small because of the short separation of the thermometers and because of the large thermal conductivity of the substrate. The temperature drop across the ¢lm is then determined by taking the di¡erence between the experimental temperature rise of the heating strip and the predicted temperature rise of the substrate at the heater location. The heat spreading into the ¢lm is typically neglected for low-thermal-conductivity ¢lms, and a onedimensional heat conduction model is used to determine the thermal conductivity of the ¢lm. For high-thermal-conductivity ¢lms such as silicon, heat spreading may allow the in-plane thermal conductivity for special sample con¢gurations to be determined, as discussed later. The thermal boundary resistance between the heater and the substrate could also be determined by performing the experiment with the thermometer array deposited directly onto the substrate.27 Because the measurement is done at steady state, the boundary condition at the backside of the substrate is important for determining the temperature underneath the heater. 2.2. In-Plane Thermal Conductivity Measurements As shown in Fig. 1, the main challenge in determining the in-plane thermal conductivity of a thin ¢lm is estimating the heat transfer rate along the ¢lm because the heat leakage to the substrate can easily overwhelm the heat £ow along the ¢lm. To address this issue, several strategies have been developed, such as (1) depositing the ¢lms on thin substrates of low thermal conductivity, (2) making freestanding ¢lm structures by removing the substrate, (3) using microheaters and temperature sensors and/or special sample con¢gurations to sense the lateral heat spreading in the ¢lm.

L

x

w

Heater/T sensor

FILM

d Substrate

(a)

T sensor

Sec. 2

ELECTRICAL HEATING AND SENSING

215

L x

w

d

I

ELECTRICALLY CONDUCTIVE FILM

Substrate

(b)

Thermal Insulation

Narrow Heater

Heater

Narrow Heater

Wide Heater

Thermal Insulation

Substrate

Substrate

Substrate

(c) FIGURE 5 Major experimental methods for in-plane thermal conductivity characterization: (a) con¢guration of the membrane method; (b) con¢guration of the bridge method; (c) in-plane heat spreading methods using buried thermal barriers and narrow-width heaters. A qualitative comparison between the spreading e¡ects of narrow and wide heaters is shown.

216 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

Several in-plane thermal conductivity measurements have been developed with the ¢rst two strategies by making suspended structures.2940 Representative concepts are shown in Fig. 5. In one con¢guration the heater and temperature sensors are fabricated on a large membrane (Fig. 5a).3039 The membrane can be a thin¢lm-on-thin-substrate structure suspended between massive heat sinks; 29;30 or the substrate underneath the ¢lm may be removed over an area, making the ¢lm a freestanding structure with the frame playing the role of a heat sink.3238 In both situations, heat generated from the heater spreads from the middle of the membrane toward its edges and the temperature pro¢le is detected by one32 (the heater itself), two,3438 or more thermometers39 situated at various locations of the membrane. Alternatively, the membrane can be shaped as a cantilever beam and the heater can be suspended at one edge,33;35;40 in which case the heat will be conducted toward the heat-sink edge of the ¢lm. On the other hand, if the membrane is conducting or semiconducting, another con¢guration shown in Fig. 5b is to shape the membrane into a bridge and to pass current directly through the ¢lm.29;31 In this case heat spreads out along the bridge axis direction and the average temperature of the bridge is measured and correlated to the thermal conductivity. The in-plane thermal conductivity of ¢lm-on-thick-substrate systems can be measured by exploring the heat spreading e¡ect (Fig. 5c) into the ¢lm by using small heaters10;23 or buried thermally insulating layers, which provide additional thermal resistance between the ¢lm and the substrate, to force more heat £ow along the ¢lm plane direction.41;42 The foregoing strategies and their applications to various in-plane thermal conductivity methods will be discussed in greater detail. 2.2.1. Membrane Method The principle of the membrane method for the in-plane thermal conductivity characterization is shown in Fig. 5a. The membrane ¢lm is supported around the edges by a relatively massive frame, usually the substrate onto which the ¢lm is grown, which also plays the role of heat sink. In the middle of the membrane, parallel with the membrane width, a thin, narrow strip of electrically conducting material acts as a heater and temperature sensor when electrical current passes through it. The temperature rise of the heater is determined typically by measuring the change in its electrical resistance. The experiments are performed in a vacuum ambient to minimize the e¡ect of convection heat transfer. The temperature response of the strip under steady-state, pulsed, and modulation heating, coupled with appropriate heat transport modeling, can be used to determine the thermal conductivity, thermal di¡usivity, and heat capacity of the membrane. Steady-State Methods. The steady-state heating method for in-plane thermal conductivity measurement is discussed ¢rst, followed by transient heating techniques. In the simplest case, assuming one-dimensional steady-state heat conduction in the plane of the ¢lm and along the direction perpendicular to the axis of the heating strip, the thermal conductivity of the ¢lm can be determined as pL ; ð14Þ k¼ wd ðTh Ts Þ where p=w is power dissipated in the heater per unit length, L is the distance from

Sec. 2

ELECTRICAL HEATING AND SENSING

217

the heater to the heat sink, T h is the heater temperature rise, and T s is the temperature of the sink. If the membrane is made of more than one ¢lm, and/or the substrate is not an ideal heat sink, a more complex thermal resistance network should be employed instead. Figure 6 shows an example of a one-dimensional thermal network used to describe the heat conduction in a Si membrane.43 In this experimental con¢guration the heater at the center of the membrane, which also acts as a resistive thermometer, is electrically insulated from the Si membrane by a Si3 N4 layer. The thermal resistance network thus includes the thermal resistance of the Si3 N4 ¢lm directly underneath the heater, the silicon membrane resistance, the spreading thermal resistance of the substrate, and contact resistance between the silicon substrate and a large heat sink. The spreading resistance in the substrate and thermal contact resistance can be important if the measured membrane has a relatively high thermal conductivity. In order to determine the substrate spreading resistance, a temperature sensor should be deposited on the substrate at the place where the membrane meets the substrate. Alternatively, temperature sensors can also be deposited on the membrane. Such an arrangement, however, can lead to complications due to the (usually) high thermal conductivity of the sensor material, which can create additional heat leakage along the temperature sensors. Figure 7 shows the various thermal resistances determined experimentally as a function of temperature. The thermal resistance of the Si3 N4 layer is determined from experimentally measured thermal conductivity of the Si3 N4 layer by using the 3! method. The in-plane thermal conductivity of the silicon membranes is calculated by isolating the thermal resistance of the membrane, RMembrane , from the total thermal resistance, Rheater , after subtracting the thermal resistance of the Si3 N4 layer underneath the heater. The combined spreading and the contact resistance in the substrate and between the substrate and sample holder are determined by the edge temperature sensor. Figure 7b shows an example of the measured thermal conductivity of a 4.67-m-thick silicon membrane, as determined by the aforementioned method, together with bulk experimental data of silicon. Several conditions must be met in order to ful¢ll the one-dimensional approximation: (1) the designed geometry of the membrane must force heat conduction in the ¢lm along the direction perpendicular to the heater length; (2) the heat con-

Heater

T sensor Si2N3 FILM Si FILM

Si Sub.

Sample Holder

(a)

(b)

FIGURE 6. (a) Sketch of the sample and (b) thermal resistance network for a membrane on a nonideal heat sink.

218 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION 3

10

R

THERM AL RESISTANCE

Solid SOI Mem brane

10

10

R R

2

R

heater sensor

/2

Nitride

mem brane

1

0

10 1 10

3

THERMAL CONDUCTIVITY (W /m K)

10

Bulk Si

SO I Thin Film (Exp.) Bulk Silicon 2

2

10 TEMPERATURE (K)

(a)

10

3

10 50

100 TEMPERATURE (K)

300

(b)

FIGURE 7 (a) Experimentally determined thermal resistance, including the total heater thermal resistance, the Si3 N4 thermal resistance, and the heat sink thermal resistance for sample con¢guration as shown in Fig. 6(a); and (b) thermal conductivity of a 4.67-m single-crystal silicon membrane together with that of bulk silicon crystal.

duction loss along the heater and temperature sensors must be reduced to a minimum; (3) radiation loss must be minimized. One way to address the ¢rst requirement is to shape the membrane as a cantilever beam connected with just one side to the substrate while the heater is suspended at the opposite side,33;35 as opposed to anchoring the membrane with all sides to the substrate. To reduce heat conduction loss along the heater and temperature sensors, one can use IC fabrication methods to minimize the heater/sensor cross-sectional area. Finally, the radiation heat loss can be reduced by performing the experiments under small temperature rise or by coating the high-temperature-rise areas with low-emissivity materials. However, if the aforementioned conditions cannot be met, more sophisticated heat transport models must be applied to determine the in-plane thermal conductivity of the ¢lm. Alternatively, AC or transient-based heating and measurements can reduce the e¡ects of heat loss through the metal heater and by thermal radiation.34 The following paragraphs describe several implementations of in-plane thermal conductivity characterization by steady-state membrane methods. In the ¢rst example bulk heaters and temperature sensors are employed, while in the second example the membrane is instrumented with a microfabricated heater and microfabricated temperature sensors. Additional reports using microfabricated test structures are brie£y discussed. In one of the earliest methods40 to determine the in-plane thermal conductivity of thin ¢lms, pairs of ¢lm-on-substrate and bare substrate specimens with identical dimensions are mounted with one side onto a large common block while the other sides are suspended. On the side opposite to the common block, a small piece of lead sheet serving as a radiative heat sink is attached to each membrane. The experiment is carried out in vacuum by heating the common block above the ambient temperature, which is kept constant. The method does not use microfabricated thermometers. Instead, ¢ne thermocouples are used to monitor the temperature of the common block and each suspended heat sink. The heat transfer rate

Sec. 2

ELECTRICAL HEATING AND SENSING

219

through each sample is calculated from the radiative heat loss to the ambient of the suspended heat sink. A one-dimensional heat conduction model is used to relate the temperature drop along the samples to the heat transfer rate and to infer the thermal conductivity of the ¢lm from the di¡erence between the e¡ective thermal conductivities of the ¢lm-on-substrate and bare substrate samples. The method relies on one’s capability of making geometrically identical sample and substrate specimens, with identical heat sinks attached to each sample, and is limited to ¢lmon-substrate systems on which the in-plane heat conduction along the ¢lm is signi¢cant compared to the total heat £ow through the ¢lm-on-substrate system, such as copper ¢lms on thin mica substrates where the reported contribution of the ¢lms was 30^35%. Moreover, careful consideration must be given to radiation loss through the membrane itself if the sample has a large emmissivity or if the experiment is performed at high temperature. In this technique the ¢lm thermal conductivity was extracted from the thermal conductivity of the ¢lm-on-substrate system. For su⁄cient accuracy the product of thermal conductivity and ¢lm thickness must be comparable to the product of thermal conductivity and substrate thickness. One strategy is to deposit the ¢lms on thin substrates of extremely low thermal conductivity. In this method,30 two opposite sides of the membrane are anchored between two relatively massive copper blocks, which serve as heat sinks. Through microfabrication techniques, a heater/ temperature sensor is deposited in the middle of the freestanding section of the membrane, with its axis parallel to the membrane sides that are anchored to the copper blocks. The heat transfer model assumes the heat £ow within the foil is essentially one dimensional and takes into account radiation losses and the heat conduction loss at the edges of the heater. To determine simultaneously the unknown thermal conductivity and emmissivity of the membrane, one performs measurements on at least two identical foils of the same thickness but di¡erent lengths. The properties of the insulating foils are ¢rst measured. Then thin ¢lms, either electrically conducting or insulating, can be deposited onto the free side (no heater) of the foils, and the experiment is repeated. The ¢lm properties are extracted by subtracting the foil properties from the e¡ective thermal properties of the ¢lm-onsubstrate system. The method allows for in situ thermal conductivity measurement of thin ¢lms during deposition. In this example the heating and sensing strips were patterned on the membrane through microfabrication technology.44 Due to its intrinsic advantages, such as ease of miniaturization, integration, and batch fabrication, microfabrication is employed to make better test structures for the in-plane thermal conductivity measurements. For example, the technology may allows us to selectively remove the substrate from underneath a well-de¢ned area of the ¢lm. Film-only freestanding test structures fabricated in this way make it possible to determine the in-plane thermal conductivity of low-thermal-conductivity thin ¢lms deposited on thick and high-thermalconductivity substrates. This approach has been used, for instance, to determine the thermal conductivity of silicon nitride,34 SiO2 ^Si3 N4 sandwich ¢lms,32 thermal CMOS MEMS ¢lms,35 doped polysilicon,36 and single-crystal silicon ¢lms,38 which were all initially deposited on silicon substrates. Moreover, microfabrication facilitates deposition of thermometer arrays for measuring the temperature pro¢le of the membrane at variable distances from the heater.34 39 With a small constant current passing through the sensor strip, the voltage change across the sensor re£ects the temperature changes of the ¢lm at the sensor location. This strategy reduces the uncertainty due to the unknown thermal boundary resistance between

220 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

the heater and the ¢lm underneath. However, when multiple-sensor arrays are used, the heat losses introduced by the sensors must be minimized.39 Transient Heating Methods. This section addresses thin-¢lm in-plane thermophysical properties characterization methods based on transient or periodic electrical heating and the corresponding temperature sensing. The heating source is obtained by passing a nonsteady electric current through the heating strip. Relative to the time dependence of the heating source, the transient techniques can be categorized as pulse and modulation techniques. Some techniques are used to determine both thermal conductivity and thermal di¡usivity of the ¢lm, since under transient heating the temperature response of the ¢lm depends also on its thermal mass. In the following, the pulsed heating technique is presented ¢rst, followed by the modulation heating technique. The heat pulse method employs a heat pulse induced by passing an electric current pulse through the heating strip. For a rectangular heat pulse of duration t0 and for a simple one-dimensional transient heat conduction model, the analytical solution for the temperature response T (x; t) of a thin ¢lm membrane is34 1 X 2A T ðx; tÞ T0 ¼ ðL x Þ þ Bn cosðn xÞ exp 2n t for 0 < t < t0; k n¼0 ð15Þ T ðx; tÞ T0 ¼

1 X n¼0

Bn cosðn xÞ exp 2n t 1 exp 2n t0

for t > t0 ;

where is the thermal di¡usivity along the membrane, 2A is the magnitude of the heat £ux along x, and Bn ¼

16AL kð2n þ

1Þ2 2

;

n ¼

ð2n þ 1Þ : 2L

ð16Þ

The experiments measure the transient temperature pro¢le at the sensor position during and after the heat pulse. If the speci¢c heat and density of the sample are known, the thermal di¡usivity or the thermal conductivity can be found by ¢tting the experimental temperature pro¢le with the help of Eq. (15). Some examples using the electrical pulse heating technique include thermal di¡usivity measurement of freestanding silicon nitride ¢lms,34 thermal di¡usivity and speci¢c heat capacity of SiO2 ^Si3 N4 sandwich ¢lms,34 and heat capacity of thin organic foils.30 A onedimensional theoretical model which includes radiative heat transfer is presented in Ref. 30. Modulation heating techniques employ an AC current modulated at angular frequency ! passing through the heating strip, which generates a DC and an AC heating component modulated at 2!. This is similar to electrical heating in the 3! method. The solution for the temperature rise in the membrane is the superposition between a DC temperature component and an AC temperature (T ac Þ modulated at 2! angular frequency. For modulation frequencies where the thermal penetration depth is much larger than the thickness, the temperature gradients across the membrane thickness can be neglected and heat transfer assumed to take place just in the plane of the membrane. Using complex representation, one can write the temperature rise at a position x away from the heater as

Sec. 2

ELECTRICAL HEATING AND SENSING

221

Tac ¼ ðxÞei2!t ;

ð17Þ

where is the complex amplitude of the ac temperature rise. In a purely onedimensional heat conduction model with no convection and radiation losses, the solution for the complex temperature rise in the semi-in¢nite membrane is h i q 1 mx mð2LxÞ ðxÞ ¼ ; ð18Þ e e km 1 þ e2mL qﬃﬃﬃﬃﬃ where q is the amplitude of the heat £ux generated by the heater and m ¼ i2! . Due to the membrane symmetry, half of the generated heat £ux in the heater contributes to the temperature rise. Equation (15) contains both the amplitude and the phase of the AC temperature and can be used to determine the thermophysical properties of the ¢lm by ¢tting the experimental temperature signals collected at di¡erent locations and modulation frequencies. Furthermore, if L! 1 (the heater is far away from the heat sink), Eq. (15) becomes q mx ðxÞ ¼ e ; ð19Þ km after taking the logarithm of the temperature amplitude, we obtain for Eq. (16): rﬃﬃﬃﬃ q pﬃﬃﬃﬃﬃﬃﬃﬃﬃﬃ ! lnfAmp½ðxÞg ¼ ln 0:5 0:5 lnð!Þ x: ð20Þ k The phase of the temperature signal is phase ¼

þ 4

rﬃﬃﬃﬃ ! x:

ð21Þ

Equations (17) and (18) suggest several ways to back out the thermal di¡usivity of the ¢lm. If the thermal signal is collected at the same frequency for di¡erent locations (using an array of thermometers), the thermal di¡usivity of the membrane can be inferred from the slopex of the phase (in radians) and/or the slope of the ln(Amp) plotted as a function of location x: ! ¼ : ð22Þ slope2x Furthermore, if the signal is collected at the same location x0 but for di¡erent modulation frequencies, the thermal di¡usivity of the membranepcan ﬃﬃﬃ be inferred pﬃﬃﬃ of the phase and/or the slope of the ln(Amp* !Þ plotted as a from the slope pﬃﬃﬃ ! function of ! : ¼

x20 : slope2pﬃﬃ!ﬃ

ð23Þ

In order to determine the thermal conductivity of the membrane, the temperature amplitude for di¡erent modulation frequencies is collected at x = 0 and plotted as a function of p1ﬃﬃﬃﬃ . Equation (17) implies 2! pﬃﬃﬃﬃ ﬃﬃﬃﬃ slope 1=p2! ¼ : ð24Þ k q

222 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION -4

PHASE AMPLITUDE

2

THERMAL DIFFUSIVITY (m /s)

10

-6

2

α ~4.5 x10 m /s

10

-5

10

-6

0

//

20 40 60 MODULATION FREQUENCY (Hz)

80

FIGURE 8 Thermal di¡usivity of the ¢lm calculated based on Eq. (19) as a function of the modulation frequency of the current. At low frequencies, the one-dimensional approximation is not valid, and the model yields frequency-dependent values for thermal di¡usivity.

Therefore, the thermal conductivity can be extracted by using the previously determined values of the ¢lm di¡usivity. Examples using the modulation heating technique include in-plane thermal diffusivity characterization of silicon nitride ¢lms34 and Si/Ge superlattice structures.39 For instance, Fig. 8 shows the in-plane thermal di¡usivity of a freestanding Si/Ge superlattice membrane,39 calculated by using Eq. (19) for both amplitude and phase signals and as a function of modulation frequency. At low frequencies the onedimensional approximation is not valid, and the model yields frequency-dependent values for thermal di¡usivity. For frequencies larger than 40 Hz the calculated thermal di¡usivity becomes frequency independent, indicating the applicability of the one-dimensional model. In order to include the e¡ect of lateral heat spreading, an analytical two-dimensional heat conduction model was also developed.39 2.2.2. Bridge Method The principle of the bridge method for the in-plane thermal conductivity characterization is shown in Fig. 5b. The method is only applicable if a current can pass through the ¢lm itself or another conducting layer with known properties deposited onto the ¢lm. The ¢lm is patterned as a thin strip, which bridges the gap between two heat sinks. The ¢lm itself serves as a heater and temperature sensor when an electric current passes through it. The temperature rise of the heater is determined by measuring the change in its electrical resistance. Similar to the membrane method the experiments are performed in a vacuum ambient to minimize the e¡ect of convection heat transfer. The temperature response of the strip under steady-state, pulsed and modulation heating, coupled with appropriate heat transport modeling, can be used to determine the thermal conductivity, thermal di¡usivity, and heat capacity of the ¢lm.29 In the following, applications of steady-state and transient, bridge method will be discussed.

Sec. 2

ELECTRICAL HEATING AND SENSING

223

Steady-State Methods. The bridge method constrains the heat £ow to one dimension. In this sense it avoids the potential complication of two-dimensional heat conduction e¡ects in the membrane. However, the thermal conductivity depends on temperature pro¢le along the bridge, which further depends on the radiation and convection heat losses (if the measurement is not done in vacuum) and on the thermal resistance at the two ends of the bridge. In a one-dimensional steady-state model, neglecting convection e¡ects, the average temperature of the bridge T M is45 TM T0 ¼

I 2 RðT0 Þ ; 2 kdw=2L þ 16"T03 Lw

ð25Þ

where is the Stefan^Boltzmann constant, T0 is the ambient and heat sink temperature, " is emissivity of the bridge surface, and R is the bridge electrical resistance. The unknown thermal conductivity and emissivity can be determined simultaneously by performing measurements on identical ¢lms that have di¡erent bridge lengths. The technique has been employed, for example, to determine the in-plane thermal conductivity of bismuth ¢lms29 deposited on thin insulating foils, enabling one to measure the thermal conductivity of ¢lms as thin as 10 nm and with low thermal conductivities (1 W/m-K). The ¢lms are evaporated onto very thin organic foils, as thin as 40 nm and with a thermal conductivity of 0.2^0.25 W/m-K. However, to ¢nd the thermal conductivity of the ¢lm, the substrate thermal conductivity must be known since the method does not apply for nonconducting materials (such as the organic foils used for substrates). Other in-plane thermal conductivity measurements using the steady-state bridge method have been reported for uniformly doped polysilicon bridges.31 A di¡erent embodiment of the bridge method is applicable to materials that allow embedding the heater within a spatially well-de¢ned region of the bridge by locally changing the electrical resistivity of the materials. This allows for localized heat generation and temperature sensing. One example of this approach is the thermal conductivity measurement of heavily doped low-pressure chemical-vapordeposited polycrystalline silicon ¢lms.31 In this method the polycrystalline silicon ¢lm is patterned in the shape of a bridge suspended above the silicon substrate on oxide pillars. The bridge has a narrow, lightly doped region at its center and is heavily doped elsewhere. The resistance of the heavily doped region is negligible compared with that of the lightly doped region. This doping pro¢le concentrates heating and temperature sensing at the center of the bridge when a current passes through it. Under a simple one-dimensional heat conduction model, neglecting convection and radiation losses, the temperature pro¢le along the bridge is linear. Moreover, if the bridge supports remain at the ambient temperature during heating, the thermal conductivity of the bridge can be determined from the slope of the power dissipated in the center region as a function of the center temperature of the bridge. However, to infer the temperature of the heater region, the temperature dependence of resistance must be carefully calibrated. One strategy is to submerge the setup in an oil bath with controlled temperature and to measure the current^ voltage characteristic of the bridge as a function of the bath temperature. Ideally, small currents should be used during the calibration such that negligible heating is produced into the bridge and the system can be considered isothermal. However, if the probing currents are large, the heating of the bridge center above oil temperature must be considered.31 The heating of the bridge supports may also need to be taken into account.31

224 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

Transient Heating Methods. By using heat pulse and modulation heating, one can adapt the bridge method to determine the thermal di¡usivity or the speci¢c heat capacitance of the ¢lm. Pulse heating is discussed ¢rst. In pulse heating, when an electric current is pulsed through the ¢lm the instantaneous experimental temperature rise of the ¢lm is related to the time constant of the bridge by45 TM T0 ½1 expðt= Þ: ð26Þ With a one-dimensional transient heat conduction model (which includes radiation loss), the time constant can be related to the speci¢c heat capacity of the bridge45 by cd2Lw ¼ 2 : ð27Þ kdw=2L þ 16"T03 Lw where is density and c is speci¢c heat of the bridge. Therefore, in combination with the steady-state method, which yields the thermal conductivity of the ¢lm, the transient heat pulse method can be employed to determine the speci¢c heat or thermal di¡usivity. To measure the speci¢c heat, one monitors the time dependence of the average ¢lm temperature immediately after turning on the heating voltage in a form of a step function, and ¢ts the experimental time constant with Eq. (27). For a ¢lm-on-thin-substrate bridge, the speci¢c heat of the substrate foil must be known and cannot be much larger than the ¢lm in order to perform the speci¢c heat measurements accurately. Modulation heating employs an AC current passing through the bridge. Similar to discussions from previous sections, through thermoresistive e¡ects the modulation heating generates a 3! voltage proportional to the amplitude of the temperature oscillations of the bridge. Thus, a model for heat transport under modulation heating in the bridge setup was developed.46 At low and high frequencies the exact solutions can be approximated with simpler expressions, facilitating the determination of thermal conductivity and heat capacitance of the ¢lm. At low modulation frequencies the heat capacitance of the bridge has little e¡ect on temperature rise. The thermal conductivity can be determined from the following relation between the root-mean-square values of 3! voltage (Vrms 3! Þ and current (Irms Þ, and the sample’s length 2L, cross section , thermal conductivity k, electrical resistance R, and dR/dT(R’): ;

rms ¼ V3!

3 4Irms RR 2L 4 k

ð28Þ

At high modulation frequencies the temperature signal is dominated by the heat capacity of the sample, which can be determined from the approximate expression of the 3! signal: ;

rms V3!

I 3 RR ¼ rms : 4!c2L

ð29Þ

Therefore, performing the measurements over a wide frequency range allows both thermal di¡usivity and thermal conductivity of the ¢lm to be determined with this method.

Sec. 3

OPTICAL HEATING METHODS

225

2.2.3. In-Plane Thermal Conductivity Measurement Without Substrate Removal The in-plane thermal conductivity methods presented use thin freestanding structures in order to force heat transport in the plane of the ¢lm. The techniques require either substrate removal, which implies additional complexity in making the test structures, or depositing the ¢lms on thin and low-thermal-conductivity supporting ¢lms, which may not be applicable generally, for example, if ¢lms must be grown epitaxially. Techniques for in-plane thermal conductivity measurements, without requiring the test structure preparations we have discussed, are presented here and shown schematically in Fig. 5c. Some of the techniques can be employed for simultaneous in-plane and cross-plane thermal conductivity characterization. In one technique the ¢lm to be measured is separated from the substrate by a low-thermal-conductivity layer.41;42 The heat source can be a heating strip deposited onto the ¢lm surface42 or a low-resistivity region embedded into the ¢lm41 (if the ¢lm is semiconducting). When an electric current is passed through the heater, its temperature rise is sensitive to the in-plane thermal conductivity of the ¢lm. In one report41 the steady-state temperature distribution in the ¢lm plane is detected by electrical resistance thermometry in metallic strips deposited parallel to the heater at various distances. A heat conduction model was developed to back out the thermal conductivity of the ¢lm from the experimental temperature rise and input power. The model considers heat conduction along the ¢lm and across the thermal barrier layer to the substrate. In a di¡erent example modulation heating and detection in just one strip were used.42 If a semiconducting heating strip de¢ned by pn junctions is also used as a temperature sensor, particular attention must be given to temperature calibration because the temperature coe⁄cient of resistance of semiconductors obtained under nearly isothermal calibration conditions may not be applicable to the experimental condition that has a large temperature gradient across the space-charge region of the pn junction. The heat spreading e¡ect was obtained in the foregoing method with a lowthermal-conductivity layer underneath the ¢lm to force more lateral heat spreading. Alternatively, a similar e¡ect can be obtained by using small-width heaters.20;22;23 No thermal barrier layers are necessary in this case. This method requires the simultaneous determination of the cross-plane thermal conductivity, which can be obtained with a larger-width heater (sensitive to the cross-plane transport). The temperature rise of the heating strip subjected to modulation heating and deposited on a multilayer thin ¢lm on substrate system is given by Eq. (9). As discussed in Sect. 2.1.1, the heat spreading e¡ect inside a ¢lm is proportional to the ¢lm anisotropy and to the ratio between ¢lm thickness and heater width. As the ¢lm thickness becomes much smaller than the width of the heating strip, the in-plane thermal conductivity determination becomes more di⁄cult. Anisotropic thermal conductivity measurements performed with modulation heating and a pair of di¡erent heater widths include dielectric thin ¢lms20 and semiconductor superlattices.22;24 3. OPTICAL HEATING METHODS Optical heating methods use radiation energy as the heat source. Unlike the microfabricated heater and sensor methods discussed in the previous section, opticalheating-based methods typically use the dynamic response of the sample because

226 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

Probe Laser

Ambient

Reflectance Change (Photothermal Reflection) Thermal Expansion (Photothermal-Displacement)

(Photoaco Acoustic Emission (Photoacoustic) Thermal Emission (Photothermal-Radiometry)

Probe Laser

Deflection (Mirage)

Acoustic and Thermal Emission FIGURE 9 Variation of the sample temperature under time-varying heating conditions generates di¡erent signatures that can be detected and used for obtaining the thermal di¡usivity/e¡usivity of the samples. Examples of these signatures, as shown, are the thermal emission, refractive index change in both the sample and the surrounding media, and the thermal expansion in both the solids and the surrounding media.

it is usually di⁄cult to determine exactly the amount of heat absorbed in the sample. From the temporal response caused by the sample temperature rise, the thermal di¡usivity or thermal e¡usivity (the product of the thermal conductivity and the volumetric speci¢c heat) of studied samples is often obtained, rather than direct measurements of the thermal conductivity of the sample. Because the density and speci¢c heat of dense thin ¢lms normally do not change signi¢cantly from their corresponding bulk materials, the bulk density and speci¢c heat can be used to backout the thermal conductivity of thin ¢lms. The variation of the sample temperature under time-varying heating conditions generates di¡erent signatures that can be detected and used for obtaining the thermal di¡usivity/e¡usivity of the samples. Examples of these signatures, as shown in Fig. 9, are the thermal emission, refractive index change in both the sample and the surrounding media, and the thermal expansion in the solids and the surrounding media. All these signatures have been explored in the past to determine thin-¢lm thermal di¡usivity/e¡usivity. Conference proceedings and monographs on photothermal and photoacoustic phenomena are excellent resources on these methods.47;48 We will divide our discussion into time-domain methods and frequencydomain methods. Time-domain methods typically use pulse heating and measure the decay of thermally induced signals, while frequency-domain methods employ modulated heating and measure the amplitude and phase of thermally induced signals. Time-domain signals contain more information because a transient heat pulse includes many di¡erent frequency components, but the signals have larger noise compared to frequency-domain signals that can be detected by phase-sensitive lock-in techniques. 3.1. Time-Domain Pump-and-Probe Methods For thin-¢lm thermophysical properties measurements, it is usually desirable to

Sec. 3

OPTICAL HEATING METHODS

227

have the pulse length shorter than the thermal penetration depth of the ¢lm. Put in terms of order of magnitude, this can be written t0 < d2 =3:

ð30Þ

For a ¢lm thickness of 1 micron and thermal di¡usivity of 105 m2 /s, the thermal signal should be collected in less than 107 s to avoid the in£uence of the substrate. This constraint requires that the heating pulse be much shorter than 107 s. A commercial available laser-£ash apparatus typically cannot reach such a temporal resolution. In the past, femtosecond, picosecond,49;50 and nanosecond lasers51 were used in the measurement of the thermal di¡usivity of thin ¢lms. The temperature response is typically probed with another laser beam through the change of the re£ectivity of the samples caused by the temperature dependence of the refractive index. For this reason pulsed laser heating and photothermal re£ectance probing are also called the pump-and-probe method. Typically, the re£ectivity (r) of the samples varies with temperatures only slightly : 1 dr 103 105 ; ð31Þ r dT with metals typically on the order of 105 and semiconductors in the range of 103 ^ 104 , depending on the laser wavelength. In most cases, to create surface heating and to avoid the complication of electron^hole generation and transport, metalcoated surfaces are preferred. The small temperature dependence of the re£ectance means that the thermal signal is small. For a 10o C temperature rise, for example, the thermal signal creates a change of only 104 in the re£ected power.50 Such a small change can be easily overwhelmed by the noise of the probe laser or the detection circuit. For nanoscale laser heating the temporal temperature response can be directly measured with fast radiation detectors. The temperature variation generated by a single pulse is captured, but averaging of many pulses is needed to reduce the noise.51 For femtosecond and picosecond laser heating, photodetectors are not fast enough, and the temporal response is often measured by a time-delayed probe beam. Thermal response to a single pulse is inferred from repetitive measurements

(a) (b) (c)

Time Delay

(d) FIGURE 10 Illustration of a time-delayed pump-and-probe detection scheme: (a) heating laser pulse trains are externally modulated; (b) temperature response of the sample to each pulse; (c) re£ectance of the probe beam, time-delayed relative to the heating beam, has a small change that depends on transient temperature; and (d) detector measures an average of many re£ected pulses within each modulation period; this average signal has a small change that is proportional to the small re£ectance change of each pulse and is detected by a lock-in ampli¢er.

228 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

of the probe response to many identical heating pulses. Figure 10 explains the basic idea behind such a time-delayed pump-and-probe method. The laser pulse trains from mode-locked pulse lasers such as a Ti^sapphire laser typically have pulse durations of 10 14 ^10 11 s, and the pulse is repeated about every 100 MHz (Fig.10a). The laser beam is externally modulated by an acousto-optic modulator at a few MHz for phase-locked detection of the small thermal signal. The thermal response of the sample, under the quasi steady-state condition, is shown in Fig. 10b. For detection of the thermal response following heating, a probe laser beam, split from the same laser beam, is directed onto heating area. This probe laser beam has a controllable, longer path length, which creates a time delay relative to the heating (pumping) beam. Due to the temperature rise, there will be a small modulation in the re£ected (or transmitted) probe pulses falling in the period when the pump pulses are not blocked by the external acousto-optic modulator (Fig.10c). The photodetector averages over a number of the probe laser pulses (Fig.10d), and the small power variation in the time-averaged re£ectance signal of the probe beam is picked up by a lock-in ampli¢er. The amplitudes of the probe beam intensity variation at di¡erent delay times give the thermal response of the sample to the pulse train. This response is often interpreted as that of a single pulse. The time-delayed pump-and-probe method was originally developed to study the nonequilibrium electron^phonon interactions and was later adapted for a variety of applications, including the thermal di¡usivity measurement of thin ¢lms and superlattices,49;50 the study of thermal boundary resistance,52 ¢lm thickness determination, and the study of acoustic phonons.53 A variety of factors should be considered in the time-delayed pump-and-probe experiment. Some key considerations will be explained later. The ¢rst factor is the time period to be examined. Figure 11 shows a typical probe-response curve to femtosecond laser heating of a metal ¢lm on a substrate.54 In the range of femtoseconds to a few picoseconds, the electrons and, phonons are out of equilibrium, and the probe laser response is mostly from the hot electrons.55 This region is not of interest if the purpose is to measure the thermal di¡usivity and, from which, the thermal conductivity. Also in the ¢gure are acoustic echoes

Electron-Phonon Interaction

Acoustic Reflection

FIGURE 11 Typical behavior of a photothermal re£ectance signal. (Courtesy of P. M. Norris)

Sec. 3

OPTICAL HEATING METHODS

229

due to re£ection of acoustic waves at the interface between the ¢lm and the substrate, which should be ignored in ¢tting for the thermal di¡usivity.56 The decay of the metallic thin-¢lm temperature after the pulse is governed by (1) thermal boundary resistance between the ¢lm and the substrate and (2) thermal di¡usion in the layers underneath, including possibly other thin ¢lms and the substrate.57 To use this method to measure the thermal conductivity of the dielectric or semiconducting thin ¢lms, one should coat the surface with a metallic thin ¢lm to absorb the laser beam. The thickness of the metallic thin ¢lm must be thicker than the absorption depth to block the laser beam, yet thin enough so that the temperature of the metallic ¢lm can be approximated as uniform during the subsequent di¡usion inside the dielectric or semiconducting ¢lm.50 The alternative of including heat conduction inside the metallic thin ¢lm is possible but introduces new uncertainties in the thermophysical properties. On the experimental side, the laser power £uctuations and the probe beam location drift caused by the mechanical delaying stage increase the experimental uncertainties. Methods to minimize these factors have been developed. The utilization of in-phase and out-of-phase components collected by the lock-in ampli¢er also provides an e¡ective way to minimize the uncertainties in the relative overlapping of the pump and probe beams.52 A few other factors should enter the consideration of the data analysis. When a large temperature gradient overlaps with the optical absorption depth, the photothermal re£ectance signal may depend on the internal temperature distribution.58 This e¡ect is important for the short period when the pump and the probe pulses overlap or immediately following the pump pulse. A more severe problem is that the surface temperature may not relax to the uniform temperature state between the pulses and thus the photothermal re£ectance signal is not the response to a signal pulse but a quasi-steady-state response to periodic pulses. Proper consideration of the pulse thermal overlap between pulses is important.50;52 A third question is on the more fundamental side. The thermal di¡usion in the substrate is often described by the Fourier heat conduction equation, which is not valid when the time scale of the event is comparable to the phonon relaxation time. Existing experiments show that the thermal conductivity of the substrate inferred from the long time-decay signals is lower than bulk values.57 Although this may be due to the interface microstructures, the nonlocal phonon transport can be another reason.59 At this stage no systematic studies exist to clarify this problem. Because of the short pulse used in the time-domain pump-and-probe method, there is very little lateral heat spreading during the experiment, and the methods are mostly suitable for the measurement of transport properties along the optical axis directions, i.e., in the cross-plane directions of thin ¢lms. For the in-plane thermal di¡usivity measurement, a technique called transient grating is suitable.60 This technique splits the original laser beam into three beams. Two of them are used to create a lateral interference pattern on the sample by overlapping the two incident beams at an angle. This interference pattern also creates a transient grating due to the refractive index dependence on the temperature. The third beam, again time delayed, passes through the grating and is di¡racted. By measuring the intensity of the di¡racted signal as a function of the delay time, the thermal di¡usivity along the ¢lm-plane direction can be determined. This technique has been used for the characterization of the thermal di¡usivity of high-temperature superconducting ¢lms.61

230 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

3.2. Frequency-Domain Photothermal and Photoacoustic Methods By periodically heating the samples, the signal detection can be accomplished through the use of lock-in ampli¢ers. Depending on the signature detected, various pump-and-probe methods have been developed and named di¡erently.47;48;62;63 The thermal penetration depth, determined by the modulation frequency ð/f)1=2 , is typically longer than the ¢lm thickness so that the substrate e¡ect must be taken into account in most of the experiments. This requires that the substrate properties be accurately known or determined by experiment. Some of these methods will be discussed. 3.2.1. Photothermal Re£ectance Method Similar to the time-domain pump-and-probe method, the photothermal re£ectance method in the frequency domain is completed by periodically modulating a continuous-wave heating laser, such as an argon laser or a diode laser, and detecting the small periodic change in the intensity of the re£ected beam of a continuouswave probe laser, typically a He^Ne laser or a diode laser. This re£ectance modulation is again due to the temperature dependence of the refractive index. Because the modulation is relatively slow, the probe laser is usually a di¡erent laser source such that the pump laser can be ¢ltered out before entering the detector. The photothermal re£ectance method has been used to measure the thermal di¡usivity of thin ¢lms and the ¢lm thickness.64 By scanning a focused probe beam around the pumping beam, maps of the amplitude and phase distributions can be obtained for modulation at each frequency. Such information can potentially be used to determine the anisotropic properties of thin ¢lms or to obtain the distributions of the thermal di¡usivity.65;66 For such applications, ideally, it is better to scan the probe beam with a ¢xed pump beam. In reality, however, it is better to ¢x the probe beam and scan the pumping beam, because the surface re£ectance £uctuation will impact more directly on the probe beam. The motion of the heat source during the scanning of the pump laser calls for careful consideration of the scanning speed and modulation frequency such that the ¢nal results are equivalent to the scanning of the probe beam relative to a ¢xed heating spot.67 3.2.2. Photothermal Emission Method Instead of measuring the re£ectance change caused by the heating, one can collect the thermal emission from the sample and use it to obtain the thermal di¡usivity of thin ¢lms. The ¢rst use of the photothermal emission signal was based on pulsed laser heating to measure thermal di¡usivity of thin ¢lms and thermal boundary resistance.68;69 Modulation-based techniques were also developed for thin-¢lm thermal di¡usivity measurements.70 In a photothermal radiometry experiment, the thermal emission signal from the sample is a convolution of the thermal waves and thermal emission generated in the sample. The thermal emission from the sample can be volumetric, depending on the optical properties of the sample at the detection wavelength. The volumetric emission contributes additional uncertainties to the thermophysical property determination. Thus, if the photothermal radiometry method is used for thermophysical property determination, care should be taken in the sample preparation so that thermal emission is from the surface. On the other hand, the volumetric characteristic of thermal emission (and also absorption) can

Sec. 3

OPTICAL HEATING METHODS

231

be utilized to characterize other properties of the samples, such as electron di¡usivity and recombination characteristics.71 3.2.3. Photothermal Displacement Method The radiative heating of samples also creates thermal expansion that can be measured by various methods, such as interferometry72 and the de£ection of a probe laser beam. These signals have been used to infer the thermal di¡usivity of thin ¢lms and the thermal boundary resistance between the ¢lm and the substrate.72;73 The interpretation of the photothermal displacement signal requires solving the thermoelastic equation to determine the pro¢le of the surfaces due to heating and thermal expansion, which in turn needs information on the thermal expansion coe⁄cient and Poisson ratio of the ¢lms and the substrate. These additional parameters add to the uncertainty of the thermal di¡usivity determination. Despite these disadvantages, in cases when the thermal displacement signal is much larger than photothermal re£ectance signals, such as in the measurement of polymer layers that have a large thermal expansion coe⁄cient, the use of the photothermal displacement signal may be preferable.73 3.2.4. Photothermal De£ection Method (Mirage Method) The photothermal de£ection method, sometimes also called the Mirage method, explores the de£ection of a laser beam when it passes through a temperature gradient caused by the temperature dependence of the refractive index. Usually, the temperature gradient created on the air side is utilized. This technique was originally developed to observe the optical absorption spectroscopy of materials,74 but was later extended for determining the thermophysical properties of thin ¢lms.75 77 This technique requires the knowledge of the probe beam location relative to the heating beam and relative to the heated surface. 3.2.5. Photoacoustic Method In the photoacoustic method the acoustic waves generated by the heating of the sample and the subsequent thermal expansion in the gas side can be measured and used to ¢t the thermophysical properties of the sample. The ambient £uid, typically air, is often used as the medium to couple the acoustic wave.62;78 80 The detection of the acoustic waves in the gas side often employs commercial microphones. Thermoacoustic spectroscopy has been widely used for characterizing the optical properties of solids.62 The photoacoustic signal typically depends on the thermophysical properties of the coupling gases that are usually known.81;82 Compared to the photothermal displacement method, it has fewer unknown parameters. Compared to the photothermal de£ection method, it does not need precise determination of the relative location of the probe beam and the sample. In actual determination of the thermophysical properties of thin ¢lms, however, the phase delay caused by the acoustic wave propagation must be calibrated and taken into consideration in the ¢nal data processing. In addition to these photothermal techniques, other signal detector methods, such as the through pyroelectric e¡ect,83 have also been developed and employed in determining thermophysical properties of thin ¢lms. In the next section we

232 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

discuss also the use of a thermoelectric response as a signal to determine thermal di¡usivity. 4. OPTICAL^ELECTRICAL HYBRID METHODS Hybrid methods that combine electrical heating and optical detection, or vice versa, are also used. One well-developed method is the AC calorimetry method, in which a laser beam is used to heat the sample and the detection is done by small thermocouples or sensors directly patterned onto the sample, as shown in the insert of Fig. 11.6;84 The distance between the laser and the sensor is varied. Under appropriate conditions the thermal di¡usivity along the ¢lm plane can be calculated from phase or amplitude data. Figure 12 gives an example of the phase data for GaAs/AlAs superlattices.85 For the in-plane property measurement, commercially available thermocouples can satisfy the required frequency response because heating is typically limited to a few Hz up to 100 Hz. For the cross-plane thermal di¡usivity, however, the thermocouple response is too slow. Chen et al.86 employed microfabricated resistance thermometers and modulated optical heating to obtain the thermal di¡usivity perpendicular to the cross-plane direction of short-period GaAs/ AlAs superlattices used in semiconductor lasers. Although commercial thermocouples have a slow response, the thermoelectric e¡ect is not limited to between two thermocouple strips. A thermocouple can be made by using a conducting ¢lm as one leg of the thermocouple and a sharpened metallic strip pressed onto the ¢lm as the other leg. Such a thermocouple does not have a junction mass and can have fast thermal response. Such a photothermo-

0.8 ln| θ|

NORMALIZED SIGNAL

0.7

ϕ

202K

0.6

318K

0.5 0.4 0.3 0.2

f=50Hz

0.1 0

0

50 100 150 200 250 HEAT SOURCE DISPLACEMENT ( µm )

300

FIGURE 12 Normalized phase and amplitude signals as functions of the relative displacement of a laser beam away from the thermocouple in the ac calorimetry measurements of the in-plane thermal di¡usivity of a GaAs/AlAs superlattice.

Sec. 5

SUMMARY

233

electric method has been used in the con¢gurations of thermal mapping and single point measurements of thermal di¡usivity of thin ¢lms87 and nanowire composite samples.88 Figure 13 shows an image of the amplitude and phase of a gold-on-glass sample obtained with the photothermoelectric method. As an alternative to the optical heating method, the sample can be heated with an electrical signal and the thermal signal can be detected by the re£ectance change51 or thermal emission from the sample.89 As discussed before, one advantage of electrical heating is that power input can be determined precisely. Optical-based detection, however, does not provide this advantage because the detected signals are usually not the absolute temperature rise of the sample. 5. SUMMARY In this chapter we summarized various methods developed for thin-¢lm thermophysical property measurements. We divide the measurement techniques into three categories : (1) electrically based, (2) optically based, and (3) a hybrid of optical and electrical. Electrical heating and sensing methods have the advantage that the power input into the sample and the temperature rise can be precisely determined, which allows direct deduction of thermal conductivity. Many recently developed electrical heating and sensing methods rely on microfabrication for heaters and temperature sensors. These methods, although allowing direct determination of thermal conductivity and potentially thermal di¡usivity and speci¢c heat, rely heavily on the availability of microfabrication facilities. For conducting samples the external heaters and temperature sensors should be carefully instrumented to minimize the impacts of current leakage into the ¢lm. The optical heating and sensing methods, on the other hand, usually require minimal sample preparation. Since the optical power input and the temperature rise are more di⁄cult to determine, thermal di¡usivity is measured, rather than a direct measurement of thermal conductivity, by ¢tting the normalized time response of sample under transient heating. Such ¢tting often requires the speci¢c heat and density of the samples as input parameters. Despite the large number of techniques developed in the past for thin-¢lm thermophysical property measurements, this chapter shows that thin-¢lm thermophy-

(a) Amplitude signal

(b) Phase signal

FIGURE 13 Two-dimensional normalized phase and amplitude signals as functions of the relative displacement of a laser beam away from the thermocouple junction in the photothermoelectric method.

234 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION

sical properties measurement is by no means easy. The choice of methods depends on sample constraints and available facilities. 6. ACKNOWLEDGMENTS T. B. would like to acknowledge the ¢nancial support of NSF (DMR-0210587) on nanoscale thermoelectric properties characterization. G. C. would like to acknowledge the contributions from his group on thermophysical property characterization, and including D. Song, W. L. Liu, B. Yang, D. Borca-Tasciuc. G. C. would also like to acknowledge the ¢nancial support of DOE (DE-FG02-02ER45977) on heat transfer in nanostructures, NSF (CTS-0129088) on nanoscale heat transfer modeling, and DoD/ONR MURI on thermoelectrics. 7. REFERENCES 1. 2. 3.

4. 5. 6. 7. 8. 9.

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Sec. 7

18.

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236 Chap. 2.2 EXPERIMENTAL TECHNIQUES FOR THIN-FILM THERMAL CONDUCTIVITY CHARACTERIZATION 43. D. Song Phonon Heat Conduction in Nano and Micro-Porous Thin Films Ph.D. Thesis, University of California at Los Angeles, Department of Mechanical and Aerospace Engineering, 2003. 44. M. Madou Introduction to microfabrication (CRC Press, 1997). 45. F. Volklein and T. Starz Thermal Conductivity of Thin Films ^ Experimental Methods and Theoretical Interpretation Proc. 16th Int. Conf. on Thermoelectrics (IEEE, (1997), pp. 711^718. 46. L. Lu, W. Yi, and D. L. Zhang 3! Method for Speci¢c Heat and Thermal Conductivity Measurements Rev. Sci. Instrum. 72, 2996^3003 (2001). 47. A. Mandelis Principles and Perspectives of Photothermal and Photoacoustic Phenomena (Elsevier, New York; 1992). 48. F. Scudieri and M. Bertolotti, eds., Photoacoustic and Photothermal Phenomena Proc. 10th Int. Conf., Rome, (AIP 1998). 49. C. A. Paddock and G. Eesley Transient Thermore£ectance from Thin Metal Films J. Appl. Phys. 60, 285^290 (1986). 50. W. S. Capinski, H. J. Maris, T. Ruf, M. Cardona, K. Ploog, and D. S. Katzer Thermal-Conductivity Measurements of GaAs/AlAs Superlattices Using a Picosecond Optical Pump-and-Probe Technique Phys. Rev. B 59, 8105^8113 (1999). 51. K. E. Goodson, O. W. Kading, M. Rosler, and R. Zachai Experimental Investigation of Thermal Conduction Normal to Diamond-Silicon Boundaries J. Appl. Phys. 77, 1385^1392 (1995). 52. R. M. Costescu, M. A. Wall, and D.G. Cahill Thermal Conductance of Epitaxial Interfaces Phys. Rev. B 67, 054302 (1^5) (2003). 53. H. Y. Hao and H. J. Maris Study of Phonon Dispersion in Silicon and Germanium at Long Wavelengths Using Picosecond Ultrasonics Phys. Rev. Lett. 84, 5556^5559 (2000). 54. P. M. Norris, A. P. Caffrey, R. Stevens, J. M. Klopf, J. T. McLeskey, and A. N. Smith Femtosecond Pump-Probe Nondestructive Evaluation of Materials Rev Sci. Instrum. 74, 400^406 (2003). 55. G. L. Eesley Observation of Nonequilibrium Electron Heating in Copper Phys. Rev. Lett. 51, 2140^ 2143 (1983). 56. K. A. Svinarich, W. J. Meng, and G. L. Eesley Picosecond Acoustic Pulse Re£ection from a MetalMetal Interface Appl. Phys. Lett. 57, 1185^1187 (1990). 57. R. J. Stoner and H. J. Maris, Kapitza Conductance and Heat Flow Between Solids at Temperatures from 50 to 300 K Phys. Rev. B 48, 16373^16387 (1993). 58. G. Chen and C. L. Tien Internal Re£ection E¡ects on Transient Photothermal Re£ectance J. Appl. Phys. 73, 3461-3466 (1993). 59. G. Chen Ballistic-Di¡usive Heat Conduction Equations Phys. Rev. Lett. 85, 2297^2300 (2001). 60. H. J. Eichler Laser-Induced Dynamic Gratings (Springer-Verlag, Berlin, 1986). 61. C. D. Marshall, I. M. Fishman, R. C. Dorfman, C. B. Eom, and M. D. Fayer Thermal Di¡usion, Interfacial Thermal Barrier, and Ultrasonic Propagation in Yba2Cu3O7-x Thin Films: Surface-Selective Transient-Grating Experiments Phys. Rev. B 45, 10009^10021 (1992). 62. A. C. Tam Applications of Photoacoustic Sensing Techniques Rev. Modern Phys. 58, 381^434 (1986). 63. K. Katayama, H Yui, T. Sawada Recent Development of Photothermal and Photoacoustic Spectroscopy Jpn. Soc. Appl. Phys. 70, 272^276 (2001). 64. A. Rosencwaig, J. Opsal, W. L. Smith, and D. L. Willenborg Detection of Thermal Waves Through Optical Re£ectance Appl. Phys. Lett. 46, 1013^1015 (1985). 65. L. Pottier Micrometer Scale Visualization of Thermal Waves by Photore£ectance Microscopy Appl. Phys. Lett. 64, 1618^1619 (1994). 66. G. Langer, J. Hartmann, and M. Reichling Thermal Conductivity of Thin Metallic Films Measured by Photothermal Pro¢le Analysis Rev. Sci. Instrum. 68, 1510^1513 (1997). 67. T. Borca-Tasciuc and G. Chen Temperature Measurement of Fine Wires by Photothermal Radiometry Rev. Sci. Instrum. 68, 8040^8043 (1997). 68. W. P. Leung and A. C. Tam Thermal Di¡usivity in Thin Films Measured by Noncontact SingleEnded Pulsed-Laser Induced Thermal Radiometry Opt. Lett. 9, 93^95 (1984). 69. W. P. Leung and A. C. Tam Thermal Conduction at a Contact Interface by Pulsed Photothermal Radiometry J. Appl. Phys. 63, 4505^4510 (1988). 70. J. A. Garcia, A. Mandelis, B. Farahbakhsh, C. Lebowitz and I. Harris Thermophysical Properties of Thermal Spray Coatings on Carbon Steel Substrates by Photothermal Radiometry Int. J. Thermophys. 20, 1587^1602 (1999). 71. A. Mandelis, A. Othonos, and C. Christofides Non-Contacting Measurements of Photocarrier Lifetimes in Bulk- and Polycrystalline Thin-Film Si Photoconductive Devices by Photothermal Radiometry J. Appl. Phys. 80, 5332^5341 (1996).

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72. B. S. W. Kuo, J. C. M. Li, and A. W. Schmid Thermal Conductivity and Interface Thermal Resistance of Si Film on Si Substrate Determined by Photothermal Displacement Interferometry Appl. Phys. A, Solids Surf. A55, 289^296 (1992). 73. C. Hu, E. T. Ogawaa and P. S. Ho Thermal Di¡usivity Measurement of Polymeric Thin Films Using the Photothermal Displacement Technique, II. On-Wafer Measurement J. Appl. Phys. 86, 6028^6038 (1999). 74. A. C. Boccara, D. Fournier, and J. Badoz Thermo-Optical Spectroscopy: Detection by the ‘‘Mirage E¡ect’’ Appl. Phys. Lett. 36, 130^132 (1980). 75. J. P. Roger, F. Lepoutre, D. Fournier, and A. C. Boccara Thermal Di¡usivity Measurement of Micron-Thick Films by Mirage Detection Thin Solid-Films 155, 165^174 (1987). 76. P. K. Kuo, M. J. L Lin, C. B. Reyes, L. D. Favro, R. L. Thomas, D. S. Kim, S. Y. Zhang, J. L. Ingelhart, D. Fournier, A. C. Boccara, and N. Yacoubi Mirage-E¡ect Measurement of Thermal Di¡usivity, Part I: Experiment Can. J. Phys., 64, 1165^1167 (1986). 77. P. K. Wong, P. C. Fung, H. L. Tam, and J. Gao Thermal-Di¡usivity Measurements of an Oriented Superconducting Film-Substrate Composite Using Mirage Technique Phys. Rev. B 51, 523^533 (1995). 78. M. Akabori, Y. Nagasaka, and A. Nasashima Measurement of the Thermal Di¡usivity of Thin Films on Substrate by the Photoacoustic Method Int. J. Thermophys. 13, 499^514 (1992). 79. J. Xiao, M. Qian, and M. A. Wei Detection of Thermal Di¡usivity of Thin Metallic Film Using a Photoacoustic Technique J. Phys. IV Colloq. 2 (C1), 2809^812 (1992). 80. X. Wang, H., Hu, X., Xu Photo-Acoustic Measurement of Thermal Conductivity of Thin ¢lms and Bulk Materials J. Heat Transfer 123, 138^144 (2001). 81. A. Rosencwaig and A. Gersho Theory of the Photoacoustic E¡ect with Solid, J. Appl. Phys. 47, 64^69 (1976). 82. H. Hu, X. Wang, and X. Xu Generalized Theory of the Photoacoustic E¡ect in a Multilayer Material J Appl. Phys. 86, 3953^3958 (1999). 83. H. Coufal and P. Hefferle Thermal Di¡usivity Measurements of Thin Films with Pyroelectric Calorimeter Appl. Phys. A 38, 213^219 (1985). 84. X. Y. Yu, Z. Liang, and G. Chen Thermal-Wave Measurement of Thin-Film Thermal Di¡usivity with Di¡erent Laser Con¢gurations Rev. Sci. Instrum. 67, 2312^2316 (1996). 85. X. Y. Yu, G. Chen, A. Verma, and J. S. Smith Temperature Dependence of Thermophysical Properties of GaAs/AlAs Periodic Structure Appl. Phys. Lett. 67, 3554^3556 (1995), 68 1303 (1996). 86. G. Chen, C. L. Tien, X. Wu, and J. S. Smith Measurement of Thermal Di¡usivity of GaAs/AlGaAs Thin-Film Structures J. Heat Transfer 116, 325^331 (1994). 87. T. Borca-Tasciuc and G. Chen Thermophysical Property Characterization of Thin Films by Scanning Laser Thermoelectric Microscope Int. J. Thermophys. 19, 557^567 (1998) 88. D. Borca-Tasciuc, G. Chen, A. Borchevsky, J.-P. Fleurial, M. Ryan, Y.-M. Lin, O. Rabin, and M. S. Dresselhaus Thermal Characterization of Nanowire Arrays in a-Al2 O3 , presented at 2002 MRS Fall Meeting, Nov. 26^30, Symposium V: Nanophase and Nanocomposite Materials, proceeding in press. 89. S. W. Indermuehle and R. B. Peterson A Phase-Sensitive Technique for the Thermal Characterization of Dielectric Thin Films J. Heat Transfer 121, 528^536 (1999).

Chapter 3.1

CERAMICS AND GLASSES Rong Sun and Mary Anne White Department of Chemistry and Institute for Research in Materials Dalhousie University, Halifax, Nova Scotia B3H 4J3 Canada

1. INTRODUCTION Glasses and ceramics are important materials. They have various applications, which require very high thermal conductivity (e.g., as heat sinks) to very low thermal conductivity (e.g., as thermal insulation). Understanding, and hence tailoring, the thermal conductivities of glasses and ceramics can be predicated on Slack’s ¢nding1 that for nonmetallic crystals in which phonons are the dominant heat transport mechanism, the thermal conductivity can be increased by the following factors: (1) low atomic mass ; (2) strong interatomic bonding; (3) simple crystal structure (small unit cell); (4) low lattice anharmonicity. In this chapter we have summarized selected recent ¢ndings with regard to thermal conductivities (Þ and, to a lesser extent, thermal di¡usivities of ceramics and glasses. Our selection of recent work is meant not to be exhaustive but illustrative of the factors at play in determining , with an emphasis on technological importance of the thermal conductivities of the materials. 2. CERAMICS Ceramics history dates back at least 35,000 years, but new ceramics with new applications are being developed virtually daily. Applications of ceramics are largely based on their high-temperature stability. A recent review of advanced engineering ceramics2 summarizes many novel ceramics based on monolithic, composite, and cellular architectures. In each application thermal conductivity is an important consideration.

240

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2.1. Traditional Materials with High Thermal Conductivity Materials with high thermal conductivities are required in many applications, especially those related to microelectronics. For example, a 10 K increase in temperature in a CMOS leads to a twofold increase in failure rate.3 Furthermore, thermal management in microelectronics is better if heat is uniformly dissipated,4 making high-thermal-conductivity materials desirable. 2.1.1. Aluminum Nitride (AlN) Aluminum nitride is not a new material, but its thermal properties have received intense attention during the past decade. Its applications include electronic packaging and heat sinks, because of its high thermal conductivity and the good match of its thermal expansion with that of silicon.5 9 Furthermore, it has a low dielectric constant and low loss tangent.10;11 Aluminum nitride has been proposed as an alternative to alumina and beryllia for microelectronic devices.12;13 The room-temperature thermal conductivity of pure AlN along the c-axis can be as high as 320 W m 1 K 1 ,14 but the thermal conductivity is usually considerably lower for polycrystalline AlN. By reduction in grain boundaries, the room-temperature thermal conductivity of polycrystalline AlN has been raised from about 40 W m 1 K 1 to 272 W m 1 K 1 , 15;16 which is close to the intrinsic value. However, pure AlN is di⁄cult to densify, so e¡orts have been made to include additives without decreasing thermal conductivity. Both processing and the presence of impurities can a¡ect the thermal conductivity of AlN. The presence of oxygen will reduce the thermal conductivity (the substitution of N sites by O gives concomitant Al vacancies),17 but other additives can increase the thermal conductivity. Processing that leads to reduction in grain boundaries also can be used to enhance the thermal conductivity. Additives such as rare-earth lanthanide oxides, generalized as Ln2 O3 , will e¡ectively enhance AlN’s thermal conductivity.18 In one investigation,18 starting from high-purity AlN powder and lanthanide oxide powders with average particle sizes of 1^5 m, samples with di¡erent oxide additive concentrations were uniaxially pressed at 35 MPa and then isostatically pressed at 200 MPa. The concentration of dopant was equimolar to the initial amount of oxygen in the AlN powder, assuming all the oxygen to be in the form Al2 O3 . Densi¢cation was carried out by sintering in a N2 £ow with graphite with a ramp time of 10 K/min at various temperatures above 1000o C and for varying times. Selected results from this study are shown in Table 1. From these results18 we see that Y2 O3 and Sm2 O3 are the most e¡ective additives, giving the largest increase in thermal conductivity. In all cases, annealing for a longer time also increased thermal conductivity, and, in most cases, a higher anneal temperature had the same e¡ect. Recently, Xu et al.19 have shown that the thermal conductivity of Sm2 O3 -doped AlN increases with increased sintering time and by not including packing powder in the sintering process; however, their highest roomtemperature thermal conductivity was 166 W m 1 K 1 , somewhat lower than that reported elsewhere,18 showing again the sensitivity to preparation conditions. The concentration of the additive also a¡ects thermal conductivity, as shown in Table 2 for added Y2 O3 . Thermal conductivity is maximized in this case with about 8 wt% Y2 O3 . The same conclusion was reached at higher temperatures, up to about 1200o C.18

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TABLE 1 Room-temperature Thermal Conductivities of AlN^Ln2 O3 Ceramics Sintered at Di¡erent Temperatures and for Di¡erent Durations18

(W m1 K1 Þ

Additive

4.91 8.29 3.42 3.41 3.41

wt% wt% wt% wt% wt%

Y2 O3 Lu2 O3 Sm2 O3 Nd2 O3 Pr2 O3

1850o C for 100 min

1850o C for 1000 min

1950o C for 1000 min

176 150 184 181 172

232 203 220 199 194

246 202 246 229 231

TABLE 2 The e¡ect of added Y2 O3 on the room-temperature thermal conductivity of AlN.18

Wt % Y2 O3 0 1 2 4 8 15 20 25 40 75

(W m1 K1 Þ 70 104 154 170 176 165 157 142 94 38

Studies20 of AlN with added YF3 show that this dopant can be used to reduce the intergranular oxygen content (through sublimation of YOF and formation of Y2 O3 Þ. In this way, a room-temperature thermal conductivity of AlN of 210 W m1 K1 has been achieved. The addition of lanthanide oxides and other sintering aids raises the thermal conductivity by acting as ‘‘getters’’ for oxygen impurities.18 Watari et al.21 have shown that selected sintering aids can produce high-thermal-conductivity AlN at lowered sintering temperatures, due to the reduction in liquid temperature in this system and the correspondingly lower temperature required to achieve the reaction to form metal oxide. Their results are summarized in Table 3. Li-doped AlN showed higher thermal conductivity and higher strength. In another study Watari et al. have shown that similar improvements in the room-temperature thermal conductivity of AlN can be made by ¢ring in a N2 (reducing) atmosphere with carbon.17 The N2 and carbon lead to reduction of the amount of oxygen, and, moreover, the grain boundary phase migrates to the surface of the sample. Both these e¡ects enhance thermal conductivity to as high as 272 W m1 K1 at room temperature for a sample with 8-m grains,17 i.e., very close to the value for a single crystal of AlN. However, at lower temperatures the thermal conductivity of the ceramic was much less than that of the single crystal. Analysis of the thermal conductivity of the ceramic leads to a calculated phonon mean free path of 6 m at T = 100 K, which corresponds closely to the grain size,

242

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TABLE 3 Room-temperature Thermal Conductivities of AlN Samples with Various Sintering Aids, Fired at 1600o C for 6 h21

AlN sample

(W m1 K1 Þ

4.0% LiYO2 + 0.5% CaO

0.47% Li2 O + 3.53% Y2 O3 + 0.5% CaO

3.53% Y2 O3 + 0.5% CaO

3.53% Y2 O3

180

130

100

40

so the predominant resistance is attributed to grain boundaries.18 This analysis shows that the grain boundaries are not as important at room temperature because, at T = 300 K, the phonon mean free path is much smaller than the grains. However, other studies (vide infra) have shown that maximizing the grain size is still important for increasing the room-temperature thermal conductivity. For example, a reheating step in the preparation of AlN has been found to further improve thermal conductivity.22 In this study three heating procedures were followed for Dy2 O3 /Li2 O/CaO-doped AlN: (A) sintering at 1600o C for 5 h; (B) sintering at 1600o C for 1 h, followed by reheating at 1600C for 15 h; or (C) sintering at 1600o C for 1 h, followed by reheating for 45 h. The results are presented in Table 4. A detailed study of the annealing time and the relationship to microstructure and thermal conductivity of Y2 O3 -doped AlN has been made by Pezzotti et al.23 Their results are presented in Table 5. In general, they found that longer annealing times lead to increased AlN grain sizes, larger aggregates of Y2 O3 at the junctions of AlN grains (rather than continuous wetting on isolated grains), and, hence, enhanced thermal conductivity. Similar recent studies of AlN with CaF2 and Y2 O3 con¢rm that during sintering at 1650o C the inhomogeneities move from the grain boundaries to form discrete pockets, thereby enhancing the densi¢cation and increasing thermal conductivity.24 In summary, the thermal conductivity of AlN can be maximized by reduction of oxide impurities, through the use of dopants or N2 atmosphere treatments, increase in grain size (through long sintering or annealing times), and removal of impurities from grain boundaries. TABLE 4 Thermal Conductivities at Room Temperature for Doped AlN Following Di¡erent Sintering Treatment.22

(W m1 K1 Þ Dopants in AlN

1600o C for 5 h

1600o C for 1 h, followed by 1600o C for 15 h

1600o C for 1 h, followed by 1600o C for 45 h

4% Li2 O + 2% CaO

54

64

112

0.5% Li2 O + 0.5% CaO + 7% Dy2 O3

89

95

163

0.5% Li2 O + 0.5% CaO + 9% Dy2 O3

84

90

150

Sec. 2

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243

TABLE 5 In£uence of the Anneal Time at 1800o C on the Room-Temperature Thermal Conductivity, Grain Size, Grain Boundary Thickness, and the Size of the Y2 O3 -Based Phase Trapped at Triple Junctions of the AlN Matrix of 5 wt% Y2 03 -Doped AlN23

Annealing time (h)

0

5

10

20

30

50

(W m1 K1 Þ AlN grain size (m) Grain boundary thickness (m) Y2 O3 triple-grain junction (m)

174 2.5 0.45 0.75

207 6.3 0.25 2.3

221 8.3 0.08 2.9

224 10.0 0.01 3.3

223 10.7 0:005 3.4

224 11.2 0:005 3.4

2.1.2. Silicon Nitride (Si3 N4 ) Silicon nitride (Si3 N4 ) can have a room-temperature thermal conductivity as high as 200 to 320 W m1 K1 . 25 Furthermore, its mechanical properties are superior to those of AlN, making Si3 N4 very useful as an electrical substrate. However, relatively low thermal conductivities have been reported for Si3 N4 ceramics, ranging from 20 to 70 W m1 K1 .26 Hot pressing27;28;29 and hot isostatic pressing (HIP) or a combination of these two methods30 can be used to develop high-thermal-conductivity Si3 N4 . For example, Watari et al.30 developed a HIPed Si3 N4 with a room-temperature thermal conductivity of 102 W m1 K1 perpendicular to the hot-pressing axis, compared with 93 W m1 K1 for the HIP sample. In this case the process included mixing of high-purity 0.8 m -Si3 N4 raw powder and 3.5 wt% Y2 O3 , followed by sieving, then hot pressing at 1800o C in £owing N2 , then HIP sintering at 2400o C for 2 h under £owing N2: The HIP treatment resulted in large -Si3 N4 grains, dimensions 10^50 m, and the elimination of smaller grains. The grain size is much larger than the room-temperature phonon mean free path (ca. 20 nm), showing that the predominant thermal resistance mechanism is point defects and dislocations within the grains.30 Other researchers have succeeded in improving the thermal conductivity of Si3 N4 by adding -Si3 N4 particles as seeds.3133 Although seeding leads to larger grains, the mechanical properties deteriorate. Furthermore, above a certain grain size, the room-temperature thermal conductivity no longer increases,26 for reasons described earlier. As for AlN, the thermal conductivity of Si3 N4 can be improved by the addition of dopants and control of the sintering time and temperature. For example, Si3 N4 sintered with 5 wt% Y2 O3 and 2^4 wt% MgO can have room-temperature thermal conductivities as high as about 80 W m1 K1 , if sintered at a temperature su⁄ciently high to remove Mg5 Y6 Si5 O24 .34 The ceramic Si3 N4 with the highest room-temperature thermal conductivity, 110^ 150 W m1 K1 , has been produced by chemical vapor deposition, which allowed careful control of the oxygen content.35 However, because of the millimeter-sized grains, this led to a material with poor mechanical properties. As we now know, such large grains are not required for high thermal conductivity, so there is scope

244

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for development of methods to produce small-grain, high-purity Si3 N4; which could have both high thermal conductivity and good mechanical properties. 2.1.3. Alumina (Al2 O3 ) Alumina (Al2 O3; ) is a useful ceramic because of its great abundance (aluminacontaining materials make up about 15% of the earth’s crust). Although not as high in thermal conductivity as AlN or Si3 N4 , it still has relatively high roomtemperature thermal conductivity (ca. 30 W m1 K1 Þ, low thermal expansion, and high compressive strength, making it useful where good thermal shock resistance is required. Furthermore, alumina is resistant to most chemicals, and is a good electrical insulator with high wear resistance. Therefore, alumina is extensively used for mechanical and electronic devices in the ceramic industry.36 Nunes Dos Santos et al.37 have systematically studied Nb2 O5 -doped Al2 O3 with variation in Nb2 O5 concentration and sintering temperature. Nb2 O5 is useful because of the Nb2 O5 ^Al2 O3 eutectic at 1698 K, allowing densi¢cation and, hence, enhanced mechanical properties, via formation of a transient liquid phase.38 After sintering at a relatively high temperature (1723 K), the porosity can be reduced to 3% for a sample with 6% Nb2 O5 . However, the addition Nb2 O5 has detrimental e¡ects on thermal conductivity, reducing the room-temperature value from ca. 15 to 4 W m1 K1 , when 6% Nb2 O5 is added. The plausible reason is that Nb acts as an impurity in the Al2 O3 lattice and thus increases the phonon scattering.37 It would appear that other means to improve the mechanical properties of alumina must be sought if high thermal conductivity is required. 2.2. Novel Materials with Various Applications 2.2.1. Ceramic Composites Besides traditional high-thermal-conductivity ceramics, a number of novel ceramic composite materials have been developed in recent years. 2.2.1.1. Diamond Film on Aluminum Nitride. Diamond ¢lm (up to 12 m) can be synthesized on AlN ceramic substrates (giving DF/AlN) by hot-¢lament chemical vapor deposition (HFCVD). With a high electrical resistance and low dielectric coe⁄cient, DF/AlN has potential applications in electronic devices. The room-temperature thermal conductivity has been investigated as a function of ¢lm thickness; results are given in Table 6. The thermal conductivity increased with ¢lm thickness, giving a maximum thermal conductivity of 205 W m1 K1 at room temperature, 73% greater than the AlN substrate.39 Furthermore, the adhesion of the ¢lm to the AlN is very good due to the formation of aluminum carbide. 2.2.1.2. Silicon Carbide Fiber-Reinforced Ceramic Matrix Composite (SiCCMC). Silicon carbide ¢ber-reinforced ceramic matrix composites are being developed for thermostructural materials, but most cannot be used at high temperature in air due to oxidation resistance and/or heat resistance of the ¢ber and interphase.40;41 However, Ishikawa et al.42 have reported a SiC-CMC, which maintains its strength (over 600 MPa) and stability in air up to 1600o C, with thermal conductivities as high as 35 W m1 K1 at 1000o C. The ¢bers were made from close-

Sec. 2

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245

TABLE 6 Room-temperature Thermal Conductivity of DF/AlN Composites with Varying Thicknesses of Diamond Film39

Thickness of diamond ¢lm (m)

2

6

9

12

(W m1 K1 Þ

132

183

197

206

packed, ¢ne hexagonal columns of sintered -silicon carbide crystals, with no apparent second phase at the grain boundaries. 2.2.1.3. Carbon Fiber-Incorporated Alumina Ceramics. In a continuing search for high-thermal-conductivity materials for microelectronics applications, Ma and Hng43 recently developed an Al2 O3 -layered substrate in which carbon ¢bers had been incorporated. Di¡erent thicknesses of the alumina layers were used to investigate the e¡ect of the alumina/carbon ¢ber thickness ratio. The results, presented in Table 7, show dramatic improvement of the thermal conductivity as the carbon content increases. A further favorable feature for microelectronics applications is that the dielectric constant also decreases as the carbon content increases. 2.2.1.4. Ceramic Fibers. Due to their low thermal conductivities, ceramic ¢bers have important applications related to high-temperature thermal isolation. Maqsood et al. have investigated the thermal conductivities of several commercial ceramic ¢bers as functions of temperature and load pressure,44 as summarized in Tables 8 and 9. The variation in thermal conductivity with temperature is rather small. In addition, they determined the variation of the room-temperature thermal conductivity with pressure up to 9.7 kN m2 . At most, the thermal conductivity increased by 12% (for Nextel) on increasing the load pressure. Under all these conditions Nextel/VK-80 was found to have the best thermal insulating ability. 2.2.1.5. Glass-Ceramic Superconductor. The thermal conductivities of superconductors are known to be exceptionally low below Tc because the Cooper pairs do not interact with the thermal phonons; this can allow superconductors to be used as thermal switches in the vicinity of the critical temperature.45 Recent investigations of a glass-ceramic superconductor, (Bi2 Ga Tl ÞSr2 Ca2 Cu3 O10þx , preTABLE 7 Room-Temperature Thermal Conductivity and Dielectric Constant at 7.5 MHz for CarbonFiber-Incorporated Alumina Substrates, as a Function of the Ratio of the Thickness of the Carbon layer to the Aluminum Layer.43

Thickness ratio

0

0.037

0.062

0.130

0.213

0.588

(W m1 K1 Þ Dielectric constant

8.0 6.02

12.7 3.65

15.2 3.16

22.5 3.04

30.6 2.61

52.1 1.24

246

Chap. 3.1

CERAMICS AND GLASSES

TABLE 8 Room-Temperature Thermal Conductivities of Ceramic Fibers at Ambient Pressure44

Trademark (Composition) VK (60Al2 O3 /40SiO2 Þ ABK (70Al2 O3 /28SiO2 /2B2 O3 Þ Nexel/VK-80 (80Al2 O3 /20SiO2 Þ

Temperature (K)

(W m1 K1 Þ

293 293 294

0.0376 0.0345 0.0305

TABLE 9 Room-Temperature Thermal Conductivities of Ceramic Fibers under a Load of 1.7 kN m2 44

Trademark VK-60

ABK

Nextel/VK-80

Temperature (K)

(W m1 K1 Þ

298 473 673 873 1073 298 473 673 873 1073 298 473 673 873 1073

0.0566 0.0793 0.1074 0.1320 0.1700 0.0531 0.0657 0.0721 0.1037 0.1300 0.0465 0.0501 0.0562 0.0795 0.1100

pared by melt quenching, show46 the expected decrease in thermal conductivity far below Tc , but a small peak in thermal conductivity, with of the order of 0.5 W m1 K1 (with the exact value depending on the composition), near Tc . The peak has been attributed to electron^phonon coupling.46 2.2.2. Other Ceramics 2.2.2.1. Rare-Earth Based Ceramics. Rare-earth-based ceramics have applications in the nuclear industry, particularly in neutron absorption, nuclear control rods, and radioactive waste containment. Quanti¢cation of their thermal properties, especially high-temperature thermal conductivity, is an important part of their assessment. The high-temperature thermal conductivities of LaAlO3 and La2 Zr2 O7 (high-temperature container materials, solid electrolytes and potential host materials for ¢xation of radioactive waste), SmZr2 O7 , Eu2 Zr2 O7 , Gd2 Zr2 O7 , and GdAlO3 (neutron absorption and control rod materials) are given in Table 10.47;48 In all these materials the thermal conductivity drops with increasing temperature up to about 1000 K, indicating that the dominant heat transport mechanism is phononic. As the temperature increases, the phonon mean free path decreases until it reaches its minimum value, of the order of interatomic distances. At higher

Sec. 2

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247

TABLE 10 Thermal Conductivities of Several Rare-Earth-Based Ceramics Used in the Nuclear Industry47;48

Temperature (K) (W m1 K1 Þ

673

773

873

973

1073

1173

1273

1373

LaAlO3 SmZr2 O7 Eu2 Zr2 O7 GdAlO3 La2 Zr2 O7 Gd2 Zr2 O7

2.63 1.73 1.66 6.58 2.27 1.78

2.22 1.67 1.63 4.98 1.82 1.33

2.00 1.58 1.56 4.04 1.64 1.24

1.92 1.49 1.57 3.56 1.47 1.16

1.90 1.51 1.58 3.38 1.42 1.02

1.87 1.50 1.58 3.38 1.33 0.98

1.88 1.50 1.60 3.42 1.29 1.02

1.87 1.55 1.65 3.69 1.29 0.98

temperatures the thermal conductivity increases slightly, especially for SmZr2 O7; Eu2 Zr2 O7 and GdAlO3 , indicating a contribution from radiative heat transfer.47 2.2.2.2. Magnesium Silicon Nitride (MgSiN2 Þ: Magnesium silicon nitride (MgSiN2 ), has been proposed as an alternative heat sink material for integrated circuits.1;49 Nonoptimized electrical and mechanical properties are comparable with those of Al2 O3 and AlN,49;50 and it had been suggested that the optimized roomtemperature thermal conductivity could be 30 to 50 W m1 K1 .51 Bruls et al.52 carried out a systematic study of MgSiN2 ceramics with and without sintering additives, and optimized the production of low-oxygen (< 1 wt%), fully dense, large-grain ceramics with no grain boundary phases and secondary phases as separate grains. From these samples, which gave a maximum room-temperature thermal conductivity of 21^25 W m1 K1 , they concluded that the intrinsic thermal conductivity of MgSiN2 would not exceed 35 W m1 K1 .52 2.2.2.3. Thermoelectric Ceramics. The development of novel materials for thermoelectric applications is an active ¢eld, and ceramic materials are being investigated in this context. Oxides are especially important because of their resistance to oxidation. The main aim of thermoelectrics is to develop materials with high values of the ¢gure of merit, ZT, where Z ¼ S 2 / (S is the Seebeck coe⁄cient, is the electrical conductivity), and T is the temperature (in K). Bi2x Pbx Sr3y Yy Co2 O9 is a polycrystalline ceramic with high potential as a good thermoelectric material because of its high-temperature stability. A recent study53 varied x and y and found that x ¼ y = 0.5 gave the best thermoelectric properties. The thermal conductivity (see Table 11) decreased as the temperature increased, indicating dominance of thermal phonon^phonon resistance, showing that ZT would be improved as temperature is increased. The value of ZT was 0.006 at T = 300 K, rising to 0.052 at T = 800 K. Katsuyama et al. 54 reported studies of another thermoelectric ceramic, (Zn1y Mgy Þ1x Alx O, as functions of both x and y. The thermal conductivity was found to decrease as the temperature increased, but without a systematic dependence on x when y = 0. However, the value of ZT for y = 0 was found to increase with decreasing x and increasing T , to a maximum ZT for Zn0:9975 Al0:0025 O of 0.074 at 1073 K. When x = 0.0025 and y was varied, ZT was optimized at y = 0.10,

248

Chap. 3.1

CERAMICS AND GLASSES

TABLE 11 Thermal Conductivity of Bi2x Pbx Sr3y Yy Co2 O9 , for x ¼ y = 0.553

Temperature (K)

300

400

600

800

(W m1 K1 Þ

1.0

0.9

0.8

0.8

corresponding to (Zn0:90 Mg0:10 Þ0:9975 Al0:0025 O, with a maximum ZT of 0.10 at 1073 K. 3. GLASSES 3.1. Introduction The origins of glass are thought to be in Mesopotamia, more than 5000 years ago. Although this likely was soda lime glass, we know now that many more materials are glass formers. Technically important glasses range from polymers and other soft materials to metallic alloys. Here we concentrate on the thermal conductivity and related properties of one glass family, chalcogenide glasses, i.e., those containing S, O, Se, and Te, as illustrative of several of the factors governing thermal conductivity of glasses. 3.2. Chalcogenide Glasses Chalcogenide glasses have been extensively studied for a long time. They are normally p-type semiconductors55 and can be used as switching and memory devices.56 One of the features of amorphous solids is that the thermal conductivity increases with increasing temperature and approaches a nearly-temperature-independent value near the softening temperature.57 Velinov and Gateshiki58 studied the thermal di¡usivities of Gex As40x (S/Se)60 . The thermal di¡usivity was found to vary with the average coordination number, Z, and this was explained on the basis of changes in the chemical ordering and in the network topology. Their results are summarized in Table 12. Hegab et al.59 studied another chalcogenide glass, Te82:2 Ge13:22 Si4:58 . They investigated the thermal conductivity and other properties as a function of temperature and ¢lm thickness; the results for the bulk sample are summarized in Table 13. They show an increase in thermal conductivity with increasing temperature, typical of an amorphous sample. The electrical response shows memory-type switching. Philip et al. 60 reported the thermal conductivity and heat capacity of Pb20 Gex Se80x and Pby Ge42y Se58 as functions of the Ge and Pb concentrations. The thermal conductivity increases with increasing x or y up to x = 21 and y = 8 and then decreases sharply, as summarized in Tables 14 and 15. These materials exhibit changeover from p-type to n-type semiconductors at speci¢c compositions, and the p to n transition reduces the phonon mean free path and, consequently, reduces the thermal conductivity for x > 21 and y > 8.60 Srinivasan et al.61 studied the thermal di¡usivity, optical band gap, and mean coordination number, hri, of Gex Sb5 Se90x and Gex Sb10 Se90x glasses. As shown in Tables 16 and 17, the thermal di¡usivity reaches a peak at hri= 2.6, indicating that

Sec. 3

GLASSES

249

TABLE 12 Values of Average Coordination Number, Z, and Room Temperature Thermal Di¡usivity of Gex As40x S60 and Gex As40x S60 58

x

0 0.10 0.15 0.22 0.25 0.27 0.32 0.36

Z

Thermal di¡usivity of Gex As40x S60 Thermal di¡usivity of Gex As40x Se60 (103 cm2 s1 Þ (103 cm2 s1 Þ

2.40 2.50 2.55 2.62 2.65 2.67 2.72 2.76

2.40 1.89 1.51 1.70 1.92 1.98 2.52 2.72

2.16 1.67 1.60 1.89 1.90 1.95 2.03 2.34

TABLE 13 Thermal Conductivity as a Function of Temperature for Bulk Te82:2 Ge13:22 Si4:58 59

T (K)

300

304

307

316

320

327

329

335

341

345

350

(W m1 K1 Þ

2.6

4.0

4.7

6.4

8.4

9.8

10.3

11.3

13.5

15.0

15.6

the network is most ordered at this composition and then decreases with further increase in hri. The room-temperature thermal di¡usivity of chalcogenide glasses of composition Gex Te1x has revealed a relationship between thermal properties and network ordering.62 The thermal di¡usivity exhibited peaks at x = 0.2 and x = 0.5 (see Table 18). The ¢rst peak was explained by the chemically ordered network model,63;64;65;66 in which x = 0.2 represents the crossover from a one-dimensional network to a three-dimensional network. The second peak corresponds to the formation of GeTe.62

TABLE 14 Composition Dependence of Room-Temperature Thermal Conductivity of Pb20 Gex Se80x 60

x

17

19

21

22

24

(103 W cm1 K1 Þ

3.97

3.99

4.01

3.72

3.41

TABLE 15 Composition Dependence of Room-Temperature Thermal Conductivity of Pby Ge42y Se58 60

y

0

4

6

8

10

14

20

(103 W cm1 K1 Þ

3.73

3.79

3.81

3.83

3.62

3.62

3.64

250

Chap. 3.1

CERAMICS AND GLASSES

TABLE 16 Values of Mean Coordination Number, hri, and Room-Temperature Thermal Di¡usivity of Gex Sb5 Se90x 61

x

hri

Thermal Di¡usivity (102 cm2 s1 Þ

12.5 15.0 17.5 20.0 22.5 25.0 27.5 30.0 32.5 35.0

2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75

0.81 0.85 0.88 0.95 1.06 1.26 1.69 1.55 1.28 1.15

TABLE 17 Values of Mean Coordination Number, hri, and Room-Temperature Thermal Di¡usivity of Gex Sb10 Se90x .61

x

hri

Thermal Di¡usivity (102 cm2 s1 Þ

10.0 12.5 15.0 17.5 20.0 22.5 25.0 27.5 30.0 32.5

2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75

0.93 0.99 1.01 1.08 1.21 1.58 1.94 1.85 1.81 1.71

TABLE 18 Room-Temperature Thermal Di¡usivity of Gex Te1x with Varying Concentration of Ge62

x

0.00

0.10

Thermal di¡usivity (cm2 s1 Þ

0.013

0.0090 0.027

0.20

0.25

0.30

0.35

0.40

0.50

0.65

0.80

0.003

0.003

0.003

0.004

0.015

0.006

0.008

3.3. Other Glasses As one example of other glass systems, we present the results of thermal di¡usivity measurements of vacuum-melted, low-silica, calcium aluminosilicate glass with various concentration of Nd2 O3 in Table 19:67 The thermal di¡usivity decreases as the concentration of Nd2 O3 increases, indicating that Nd3þ acts as a network modi¢er.67

Sec. 5

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251

TABLE 19 Room-Temperature Values of Thermal Di¡usivity and Thermal Conductivity of Calcium Aluminosilicate Glass of Composition 47.4 wt% CaO, (41.5 - xÞ wt% Al2 O3 , 7.0 wt% SiO2 , 4.1 wt% MgO, x wt% Nd2 O3 67

x 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0

Thermal Di¡usivity (103 cm2 s1 Þ 5.690.05 5.630.05 5.670.11 5.650.09 5.550.04 5.440.04 5.550.04 5.440.03 5.390.03 5.360.03 5.220.03

(W m1 K1 Þ 1.5480.031 1.5250.030 1.5590.043 1.5450.038 1.5340.031 1.4940.030 1.5410.031 1.4950.030 1.4900.030 1.4770.029 1.4330.029

4. CONCLUSIONS In many applications of ceramic and glass materials, appropriate thermal conductivity is intrinsically linked to their applications. Through selected examples, we have illustrated how recent advances in thermal conductivity allow us to better understand thermal conductivities of ceramics and glasses, thereby advancing uses of these important materials. 5. REFERENCES G. A. Slack Nonmetallic Crystals with High Thermal Conductivity J. Phys. Chem. Solids 34, 321^ 335 (1973). 2. P. Greil Advanced Engineering Ceramics Adv. Eng. Mater. 4, 247^254 (2002). 3. D. R. Fear and S. Thomas Emerging Materials Challenges in Microelectronics Packaging MRS Bulletin 28(1), 68^74 (2003). 4. V. P. Atluri, R. V. Mahajan, P. R. Patel, D. Mallik, J. Tang, V. S. Wakharkar, G. M. Chrysler, C.-P. Chiu, G. N. Choksi, and R. S. Viswanath Critical Aspects of High-Performance Microprocessor Packaging MRS Bull. 28(1), 21^34 (2003). 5. W. Werdecker and F. Aldinger Aluminum Nitride ^ An Alternative Ceramic Substrate for High Power Applications in Microcircuits IEEE Trans. Comp., Hybrids, Manuf. Technol. 7, 399^404 (1984). 6. Y. Kurokawa, K Utsumi, H. Takamizawa, T. Kamata, and S. Noguchi AlN Subtrates with High Thermal Conductivity IEEE Trans. Comp., Hybrids, Manuf. Technol. 8, 247^252 (1985). 7. D. G. Brunner and K. H. Wienand Metallized Aluminium Nitride Ceramics Potential, Properties, Applications Interceram. 37(4), 29^32 (1988). 8. N. Ichinose Aluminium Nitride Ceramics for Substrates Mater. Sci. Forum 34-36, 663^667 (1988). 9. F. Miyashiro, N. Iwase, A. Tsuge, F. Ueno, M. Nakahashi, and T. Takahashi High Thermal Conductivity Aluminium Nitride Ceramic Substrates and Packages IEEE Trans. Comp., Hybrids, Manuf. Technol. 13, 313^319 (1990). 10. R. R. Tummala Ceramic and Glass-Ceramic Packaging in the 1990s J. Am. Ceram. Soc. 74(5), 895^ 908 (1991). 11. A. V. Virkar Thermodynamic and Kinetic E¡ects of Oxygen Removal on the Thermal Conductivity of Aluminum Nitride J. Am. Ceram. Soc. 72(11), 2031^2042 (1989). 1.

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Sec. 5

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253

39. Y. Liao, R.C. Fang, Z. Y. Ye, N.G. Shang, S. J. Han, Q. Y. Shao, and S.Z. Ji Investigation of the Thermal Conductivity of Diamond Film on Aluminum Nitride Ceramic App. Phys. A 69, 101^103 (1999). 40. I. J. Davies, T. Ishikawa, N. Suzuki, M. Shibuya, and T. Hirokawa Proc. 5th Japan Int. SAMPE Symp. (Japan Chapter of SAMPE, Yokohama (1997), pp. 1672^1632. 41. M. Takeda, Y. Imai, H. Ichikawa, Y. Kagawa, H. Iba, and H. Kakisawa Some Mechanical Properties of SiC (Hi-Nicalon) Fiber-Reinforced SiC Matrix Nicaloceram Composites Ceram. Eng. Sci. Proc. 18, 779^786 (1997). 42. T. Ishikawa, S. Kajii, K. Matsunaga, T. Hogami, Y. Kohtoku, and T. Nagasawa A Tough, Thermally Conductive Silicon Carbide Composite with High Strength up to 1600o C in Air Science 282, 1295^1297 (1998). 43. J. Ma and H. H. Hng High Thermal Conductivity Ceramic Layered System Substrates for Microelectronic Applications J. Mater. Sci.: Mater. Electron. 13, 461^464 (2002). 44. A. Maqsood, M. Anis-ur-Rehman, V. Gumen, and Anwar-ur-Haq Thermal Conductivity of Ceramic Fibers as a Function of Temperature and Press Load J. Phys. D: Appl. Phys. 33, 2057^2063 (2000). 45. M. A. White Properties of Materials (Oxford, New York, 1999), pp. 270^271. º zdes, and H. Ates Thermal Conductivity Properties of 46. Y. Balci, M. E. Yakinci, M. A. Aksan, A. O Glass-Ceramic (Bi2 Ga Tl ÞSr2 Ca2 Cu3 O10þx High-Tc Superconductors J. Low Temp. Phys. 117, 963^967 (1999). 47. G. Suresh, G. Seenivasan, M. V. Krishnaiah, and P. S. Murti Investigation of the Thermal Conductivity of Selected Compounds of Gadolinium and Lanthanum J. Nucl. Mater. 249, 259^261 (1997). 48. G. Suresh, G. Seenivasan, M. V. Krishnaiah, and P. S. Murti Investigation of the Thermal Conductivity of Selected Compounds of Lanthanum, Samarium and Europium J. Alloys Comp. 269, L9-L12 (1998). 49. W. A. Groen, M. J. Kraan, and G. de With Preparation, Microstructure and Properties of Magnesium Silicon Nitride (MgSiN2 Þ Ceramics J. Europ. Ceram. Soc. 12, 413^420 (1993). 50. W. A. Groen, M. J. Kraan, G. de With, and M. P. A. Viegers New Covalent Ceramics: MgSiN2 Mat. Res. Soc. Symp. Proc. 327, 239^244 (1994). 51. R. J. Bruls, H. T. Hintzen, and R. Metselaar Proceedings of the Twenty Fourth International Thermal Conductivity Conference and Twelfth International Thermal Expansion Symposium (Pittsburgh, 1997), edited by P. S. Gaal, and D. E. Apostoleseu (Technomics, Pennsylvania, 1999), 3. 52. R. J. Bruls, A. A. Kudyba-Jansen, P. Gerharts, H. T. Hintzen, and R. Metselaar Preparation, Characterization and Properties of MgSiN2 Ceramics J. Mater. Sci.: Mater. Electron. 13, 63^75 (2002). 53. E. Iguchi, T. Itoga, H. Nakatsugawa, F. Munakata, and K. Furuya Thermoelectric Properties in Bi2x Pbx Sr3y Yy Co2 O9 Ceramics J. Phys. D: Appl. Phys. 34, 1017^1024 (2001). 54. S. Katsuyama, Y. Takagi, M. Ito, K. Majima, H. Nagai, H. Sakai, K. Yoshimura, and K. Kosuge Thermoelectric Properties of (Zn1y Mgy Þ1x Alx O Ceramics Prepared by the Polymerized Complex Method J. Appl. Phys. 92, 1391^1398 (2002). 55. N. F. Mott and E. A. Davis Electronic Processes in Non-Crystalline Materials (Clarendon, Oxford, 1979). 56. D. Adler Amorphous-Semiconductor Devices Sci. Am. 236(5), 36^48 (1977). 57. D. G. Cahill, J. R. Olson, H. E. Fischer, S. K. Watson, R. B. Stephens, R. H. Tait, T. Ashworth, and R. O. Pohl Thermal Conductivity and Speci¢c Heat of Glass Ceramics Phys. Rev. B 44, 12226^12232 (1991). 58. T. Velinov and M. Gateshiki Thermal Conductivity of Ge-As-Se(S) Glasses Phys. Rev. B: Condensed Matter Mater. Phys. 55(17), 11014^11017 (1997). 59. N. A. Hegab, M. Fadel, M. A. Afifi, and M. F. Shawer Temperature Dependence of Electrical and Thermal Properties of Te82:2 Ge13:22 Si4:58 Glassy Alloy J. Phys. D: Appl. Phys. 33, 2223^2229 (2000). 60. J. Philip, R. Rajesh and C. P. Menon Carrier-Type Reversal in Pb-Ge-Se Glasses: Photopyroelectric Measurements of Thermal Conductivity and Heat Capacity Appl. Phys. Lett. 78, 745^747 (2001). 61. A. Srinivasan, K. N. Madhusoodanan, E. S. R. Gopal, and J. Philip Observation of a Threshold Behavior in the Optical Band Gap and Thermal Di¡usivity of Ge-Sb-Se Glasses Phys. Rev. B 45, 8112^8115 (1992). 62. J. C. de Lima, N. Cella, L. C. M. Miranda, C. Chying An, A. H. Franzan, and N. F. Leite Photoacoustic Characterization of Chalcogenide Glasses: Thermal Di¡usivity of Gex Te1x Phys. Rev. B 46, 14186^14189 (1992).

254

Chap. 3.1

CERAMICS AND GLASSES

63. M. F. Thorpe Continuous Deformations in Random Networks J. Non-Cryst. Solids 57, 350^370 (1983). 64. J. C. Phillips and M.F. Thorpe Constraint Theory, Vector Percolation and Glass Formation Solid State Commun. 53, 699^702 (1985). 65. J. C. Phillips Vibrational Thresholds Near Critical Average Coordination in Alloy Network Glasses Phys. Rev. B 31, 8157^8163 (1985). 66. N. K. Abrikosov, V. F. Bankina, L. V. Poretskaya, L. E. Shelimova, and E. V. Skudnova Semiconducting II-VI, IV-VI and V-VI Compounds (Plenum, New York, 1969), pp. 67. 67. M. L. Baesso, A. C. Bento, A. R. Duarte, A. M. Neto, L.C.M. Miranda, J.A. Sampaio, T. Catunda, S. Gama and F. C. G. Gandra Nd2 O3 Doped Low Silica Calcium Aluminosilicate Glasses: Thermomechanical Properties J. Appl. Phys. 85, 8112^8118 (1999).

Chapter 3.2

THERMAL CONDUCTIVITY OF QUASICRYSTALLINE MATERIALS A. L. Pope and Terry M. Tritt Department of Physics and Astronomy, Clemson University, Clemson, SC, USA

1. INTRODUCTION For many decades x-ray di¡raction peaks were understood as re£ections from the periodic lattice planes in a solid-state material.1 These planes could be clearly identi¢ed and the crystal structure could be e¡ectively indexed and cataloged. Much of our understanding of structural determination of crystals was seriously challenged in the mid-1980s with the discovery of quasicrystals, or quasicrystalline materials,2 materials exhibiting ¢vefold symmetry, which were forbidden to exist in nature.3 Quasicrystals lack the long-range periodicity of a crystal and yet they exhibit ‘‘structural order’’ which leads to very sharp and distinct x-ray di¡raction peaks, in contrast to amorphous materials. These sharp and distinct x-ray di¡raction peaks could not be indexed by the then-existing crystallographic techniques which had been developed for periodic crystal structures. Quasicrystals display long-range positional order without short-range rotational symmetry.2 Over 100 quasicrystalline systems exist at present and are seen to have 5-, 8-, 10-, or 12-fold symmetries, all of which are classically forbidden. It is striking to note the high structural quality of the quasicrystals when compared with their thermal transport properties, which are more reminiscent of a glass. Quasicrystals typically exhibit thermal conductivity values on the order of 1^3 W m 1 K 1 . They are also very hard materials, and this property coupled with their low thermal conductivity has made them attractive for use as thermal barrier coatings. They have been used to coat frying pans to replace the more standard Te£on coatings. We give a brief overview of thermal transport in the two most prominently measured classes of quasicrystals.

256 Chap. 3.2

THERMAL CONDUCTIVITY OF QUASICRYSTALLINE MATERIALS

κL (W m-1 K-1)

Many quasicrystalline systems exist, but the most common quasicrystals are the AlPdMn and AlCuFe quasicrystal systems. AlPdMn quasicrystals can be synthesized in a 5-fold or 10-fold symmetry. Compositional variations exist even within a speci¢c type of quasicrystal, so the following statements are designed to be taken as generalization for the ¢vefold symmetric crystals aforementioned. The ¢vefold symmetric quasicrystals are stable and have a wealth of information available on them. At low temperatures (T < 2 K) the thermal conductivity is observed to increase as approximately T2 . The thermal conductivity then increases with increasing temperature until a phonon-saturation plateau is observed to occur between 20 K and 100 K.4 This plateau is observed at much higher temperatures in quasicrystals than in amorphous materials (Fig. 1).5 Above 100 K the thermal conductivity is observed to begin to increase again.6;7 It is observed in AlPdMn quasicrystalline systems that the lattice thermal conductivity is nearly constant above 150 K, with the small increase in thermal conduction being due to the electronic contribution. AlPdMn quasicrystals have thermal conductivity values on the order of 1^3 W m 1 K 1 at room temperature. Once again, the variation in room temperature thermal conductivity is due to di¡erent sample composition. It is also noted that the electronic thermal conductivity continues to increase as temperatures are further elevated. In fact, thermal conductivity increases until the material dissociates. AlCuFe quasicrystals are ¢ve-fold symmetric and also have thermal conductivity values about 1 and 3 W m 1 K 1 at room temperature. Thermal conductivity in these quasicrystals behaves in much the same way as AlPdMn quasicrystals. Thermal conductivity at 1000 K has been observed to be less than 10 W m 1 K 1 for AlCuFe quasicrystals.8 Perrot has calculated that the Wiedemann^Franz relation holds at high temperatures for these materials, and is within 15% of the accepted value. The validity of the Wiedemann^Franz relation indicates that the scattering rate of the electrons is proportional to that of the phonons. Perrot demonstrates that the lattice and electronic contributions to thermal conductivity in AlCuFe increase with increasing temperature.

FIGURE 1 Lattice thermal conductivity increases with increasing temperature until a phonon saturation plateau is observed in both AlPdMn quasicrystals and amorphous SiO2 .

Sec. 3

LOW-TEMPERATURE THERMAL CONDUCTION IN QUASICRYSTALS 257

2. CONTRIBUTIONS TO THERMAL CONDUCTIVITY The thermal conductivity in these materials is essentially sample independent.9 Small changes in composition, di¡erent annealing practices, and sample composition are observed to have little e¡ect on the overall magnitude of thermal conductivity, changing it by less than a factor of 2. Temperature-dependent thermal conductivity measured from 2 K to 1000 K has been observed to have values below 10 W m1 K1 for the entire temperature range.10 In general, the total thermal conductivity of a material can be written as T ¼ E þ L , where E and L are the electronic and lattice contributions respectively. The Wiedemann^Franz relationship provides a ratio of the electrical resistivity (Þ to the electronic part of the thermal conductivity (E Þ at a given temperature, which is the same for most metals (E = L0 T/Þ, where L0 is the Lorentz number (L0 = 2.45 108 (V/K)2 Þ. The Wiedemann^Franz relationship, which is well behaved in most metallic systems, has also been shown to hold in many quasicrystalline systems.11;12 To investigate the electronic contribution of the thermal conductivity utilizing the Wiedemann^Franz relationship, one analyzes the electrical conductivity of AlPdMn and AlCuFe. As is typical with many quasicrystalline systems, the electrical conductivity increases with increasing temperature. The increase in electrical conduction is contrary to Matthiessen’s rule, implying that the weak scattering approximation does not hold for quasicrystals. Electrical conductivity of these quasicrystalline systems (AlPdMn and AlCuFe) is about 102 1 cm1 . 9;13;14 Applying the Wiedemann^Franz relationship to these values of electrical conductivity, we observe that the electronic contribution to thermal conduction is negligible below 150 K and begins to in£uence the temperature dependence of the total thermal conductivity above 150 K. Thus, the thermal conductivity in the aforementioned quasicrystalline systems will be considered to be governed primarily by the lattice vibrations below 150 K. Lattice contributions continue to be signi¢cant above 150 K, but due to the continually increasing electronic contribution one must also consider the electronic portion. While electrical conduction in a quasicrystal is similar in many respects to electronic conduction in crystalline materials, thermal conduction in quasicrystals is most easily compared to that of a glass (a-SiO2 Þ, as seen in Fig. 1. In perfect crystals the lattice vibrations are described by phonons. In amorphous materials, where there is no lattice, heat is transported through localized vibrations or excitations, which are often referred to as tunneling states. These localized vibrations lead to the minimum thermal conductivity of a system.15 3. LOW-TEMPERATURE THERMAL CONDUCTION IN QUASICRYSTALS The di¡erence in scattering mechanism between crystalline and amorphous materials can be seen most acutely at low temperatures. At these temperatures (T < 2 K), phonon modes are frozen out and boundary scattering and grain size e¡ects limit the lattice thermal conductivity.16 This causes lattice thermal conductivity in crystals to behave as T3 and lattice thermal conductivity in some glasses to behave as T2 , due to boundary scattering or scattering of phonons by tunneling states.1719 Thompson has shown that both phonon scattering by electrons and tunneling states exist in quasicrystalline materials.20 Therefore, quasicrystals can be classed as two-

258 Chap. 3.2

THERMAL CONDUCTIVITY OF QUASICRYSTALLINE MATERIALS

level systems. As such, any scattering by electrons will be observed only at higher temperatures. 4. POOR THERMAL CONDUCTION IN QUASICRYSTALS Thermal conductivity in quasicrystals is two orders of magnitude lower than aluminum, which is somewhat surprising since many quasicrystals are composed primarily (70) of aluminum. The question arises, as to what mechanisms allow the thermal conduction to be so close to the minimum thermal conductivity. In amorphous materials large amounts of phonon scattering occur due to the irregular structure of these materials. The mean free path is very small and essentially temperature independent. This leads to low values of thermal conductivity, typically about 1 W m 1 K 1 at 300 K. Thompson has observed in several AlPdMn quasicrystals that above 100 K the thermal conductivities of these materials approach the minimum thermal conductivity.20 The thermal conductivity in quasicrystals can be described as glasslike due to the phonon saturation peak seen as well as the small magnitude of thermal conductivity. This glasslike thermal conductivity is attributed to the large structural coherence observed in these materials ; in AlPdMn the structural coherence can be up to . This structural coherence gives AlPdMn a large unit cell, which is a 8000 A component typically observed in low-thermal-conductivity materials.21 Janot has explained the poor thermal conductivity observed in quasicrystalline materials as being due to the reduced range of phonons due to variable-range hopping.19 An alternative explanation is that the quasiperiodic lattice scatters phonons as if a point defect exists at every atomic site.22 This gives rise to scattering such as is observed in amorphous materials. 5. GLASSLIKE PLATEAU IN QUASICRYSTALLINE MATERIALS Thermal conductivity increases with increasing temperature until a phonon saturation plateau is observed to occur between 20 K and 100 K.23 This plateau is observed at much higher temperatures in quasicrystals than in amorphous materials.24 Kalugin et al. have explained the glasslike plateau utilizing a generalized Umklapp process.25 Umklapp processes are a consequence of interplay between two scattering processes. The natural length scale for an Umklapp process is the reciprocal lattice spacing where the phonons are scattered outside the ¢rst Brillioun zone and in a reduced zone scheme appears as a backward scattering process. Of course, a reciprocal lattice or Brillioun zone does not exist for a quasicrystal. Umklapp processes in crystals will decrease exponentially, but in quasicrystals these Umklapp processes will lead to a power-law behavior of the mean free path. Kalugin et al. compared this theory with quasicrystal data and observed that it provides a reasonable explanation for the plateau-like feature observed in quasicrystalline materials. 6. SUMMARY Overall, the thermal conduction in quasicrystalline materials appears to behave in a

Sec. 7

REFERENCES

259

manner much as one would expect a glass to behave. At low temperatures, a T2 temperature dependence which is sometimes associated with some amorphous materials is evident in quasicrystals. As temperature increases, a phonon saturation plateau is observed ; as temperatures increase above 150 K, the electronic contribution of the thermal conductivity begins to become important. Quasicrystals are fascinating materials displaying electronic properties most closely related to crystalline materials and thermal properties most closely associated with amorphous materials.

7. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8.

9. 10.

11. 12.

13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25.

J. D. Winefordner, ed., Introduction to X-Ray Powder Di¡ractometry (Wiley, New York, 1996). D. Shechtman, I. Blech, D. Gratias, and J. W. Cahn Phys. Rev. Lett. 53, 1951 (1974). C. Kittel Solid State Physics (Wiley, New York) M. Chernikov, A. Bianchi, and H. Ott. Phys. (Wiley, New York, 7th Edition, 1996) Rev. B. 51, 153 (1995). W. Ha«nsch and G. D. Mahan Phys. Rev. B 28, 1886^1901 (1983). F. Cyrot-Lackmann Metastable in Nanocrystalline Mater. 1, 43^46 (1999). D. Cahill Lattice Vibrations in Glass Ph.D. Dissertation, Cornell University, 1989. A. Perrot, J. M. Duboise, M. Cassart, and J. P. Issi Quasicrystals in Proceedings of the 6th International Conference Tokyo, Japan, 1997, edited by S. Takeuchi and T. Fujiwara (World Scienti¢c, Singapore, 1998). A. L. Pope Thermal and Electrical Transport in Quasicrystals Thesis, Department of Physics, Clemson University, Clemson, SC (2002). A. Perrot, J. M. Duboise, M. Cassart, and J. Issi Quasicrystals in Proceedings of the 6th International Conference Tokyo, Japan, 1997, edited by S. Takeuchi and T. Fujiwara (World Scienti¢c, Singapore, 1998). A. Perrot, J. M. Dubois, M. Cassart. J. P. Issi Proc. 6th Int. Conf. on Quasicrystals (1997). K. Gianno, A. V. Sologubenko, M. A. Chernikov, H. R. Ott, I. R. Fisher, and P. C. Canfield Low-temperature Thermal Conductivity of a Single-Grain Y-Mg-Zn Icosahedral Quasicrystal Phys. Rev. B 62, 292 (2000). A. L. Pope, T. M. Tritt, M. A. Chernikov, and M. Feuerbacher Appl. Phys. Lett. 75, 1854 (1999). M. A. Chernikov, A, Bernasconi, C. Beeli, and H. R. Ott Europhys. Lett. 21, 767 (1993). G. A. Slack in Solid State Physics edited by F. Seitz and D. Turnbull (Academic Press, New York, 1979), Vol. 34, p. 57. D. K. MacDonald Thermoelectricity: An Introduction to the Principles (Wiley, New York, 1962). R. R. Heikes and R. Ure Thermoelectricity: Science and Engineering (Interscience, New York, 1961). N. F. Mott Conduction in Non-Crystalline Materials (Oxford Science, 1987). C. Janot Quasicrystals: A Primer (Clarendon Press, Oxford, 1992). E. Thompson, P. Vu, and R. Pohl Phys. Rev. B. 62, 11473 (2000). P. A. Bancel Quasicrystals: The State of Art (World Scienti¢c, Singapore 1991). S. Legault Heat Transport in Quasicrystals, Thesis, Department of Physics, McGill University, Montreal, Quebec (1999). M. Chernikov, A. Bianchi, and H. Ott Phys. Rev. B. 51, 153 (1995). W. Ha«nsch and G. D. Mahan Phys. Rev. B 28, 1886^1901 (1983). P. Kalugin, M. Chernikov, A. Bianchi, and H. R. Ott Phys. Rev. B 53, 14145 (1996).

Chapter 3.3

THERMAL PROPERTIES OF NANOMATERIALS AND NANOCOMPOSITES T. Savage and A. M. Rao Department of Physics and Astronomy, Clemson University, Clemson, SC USA

Interest in the science and technology of nanomaterials has exploded in the past decade mainly due to their extraordinary physical and chemical properties relative to the corresponding properties present in bulk materials. A nanostructure is characterized by its size, as indicated by the term, having its crucial dimensions on the order of 1^100 nm. There is an assortment of groupings in which nanostructures are often categorized. In this chapter our discussion on nanostructures will primarily be divided into two groups: (a) nanomaterials, consisting of such structures as nanotubes, nanowires or nanorods, and nanoparticles, and (b) nanocomposites, which include a composite material incorporating any of the aforementioned nanostructures in a matrix, in particular, thin ¢lms of polymer/nanotube composites. The extremely small ‘‘dimension’’ is what in many instances gives nanostructures their unique physical and chemical properties. Kittel lists several reasons for these unusual properties : 1 (a) a signi¢cant fraction of the atoms in a nanomaterial is composed of surface atoms, as opposed to a large fraction of interior atoms present in bulk materials ; (b) the ratio of surface energy to total energy may be of the order of unity ; (c) the wavelength of electrons in the conduction or valence band is restricted by geometric size and is shorter than the wavelength in the bulk solid; (d) a wavelength or boundary condition shift will a¡ect optical absorption phenomena; and (e) clearly de¢ned boundaries in magnetic monolayers such as, alternating ¢lms of ferromagnetic iron and of paramagnetic chromium, present an opportunity for greater control over magnetic properties by tunneling of the magnetization through the chromium barrier.

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This chapter will focus on heat transfer in nanomaterials, which depend primarily on energy conduction due to electrons as well as phonons (lattice vibrations) and the scattering e¡ects that accompany both (these include impurities, vacancies, and defects). Thermal conductivity, , the electrical conductivity, , the thermoelectric power (TEP) or Seebeck coe⁄cient, S (as it is often called), and the heat capacity, C, all provide valuable insight into important physical characteristics of the nanomaterial. Values for such quantities in nanomaterials and nanocomposites are often useful for drawing comparisons to measurements in corresponding bulk materials. These types of measurements are also important for when nanostructures are used in various applications, such as nanoelectronic devices and gas sensors. 1. NANOMATERIALS 1.1. Carbon Nanotubes We begin with the discussion of thermal properties of carbon nanotubes, which are the latest molecular form of carbon, discovered in 1991 by Iijima.2 A nanotube can be viewed as a graphene sheet rolled into a seamless cylinder with a typical aspect ratio (length/diameter) exceeding 1000. Typically, carbon nanotubes are cast into two groups: (a) single-walled (SWNTs) or (b) multiwalled (MWNTs), which are basically a set of concentric SWNTs. Carbon nanotubes are generally synthesized by one of three commonly used methods. The ¢rst is the electric arc discharge in which a catalyst-impregnated graphite electrode is vaporized by an electric arc (under inert atmosphere of 500 Torr), yielding carbon soot that deposits on the inner surface of the water-cooled arc chamber.3 In the second method, commonly known as laser vaporization, a pulsed laser beam is focused onto a catalyst-impregnated graphite target (maintained in an inert atmosphere of 500 Torr and 1200 C) to generate the soot that collects on a water-cooled ¢nger.4 Both techniques are widely used for producing SWNTs and typically yield soot with 60^70% of the sample as nanotubes and the remainder as nanoparticles. The third technique, and perhaps the one with the most promise for producing bulk quantities of nanotubes, is chemical vapor deposition (CVD). The nanotubes are formed by the pyrolysis of a hydrocarbon source seeded by catalyst particles (typically ferromagnetic particles such as Fe, Co, Ni, etc., are used) in an inert atmosphere and 700^ 1200 C. The CVD process is usually the method of choice for preparing MWNTs, although reports have shown that SWNTs can also be grown by this means.5 1.1.1. Electrical Conductivity, Since the conduction by electrons is one of the two main ways in which heat is transferred in a solid, it is important to have an understanding of the electrical conductivity, . Electron transport in nanotubes can be discussed one-dimensionally (1D) due to their high aspect ratios (i.e., diameters ranging from <1 nm to 4 nm and lengths of up to several microns).6 This characteristic of nanotubes makes them excellent candidates for use as molecular wires. Another important aspect of nanotubes to electron transport is that they can be metallic or semiconducting, depending on their diameter and chirality (a measure of the amount of ‘‘twist’’ in the lattice).7 All of the carbon atoms in the nanotube’s lattice lie entirely on the surface, leaving the tube hollow as it were. The conduction of electrons in a 1D

Sec. 1

NANOMATERIALS

263

FIGURE 1 Band structure of (10,10) armchair nanotubes. The two central bands (labeled by their di¡erent distinct symmetries) intersect at the Fermi energy, giving clear evidence of their metallic nature.9

system such as a nanotube occurs ballistically or di¡usively.8 When the electrons travel without being scattered, they are said to conduct ballistically. This type of transport will only occur in a very small nanotube segment such that its length is much shorter than the mean free path of the electron. However, in most instances this is not the case, and the conduction of electrons is highly dependent on scattering e¡ects due to such things as phonons, impurities, and structural defects. The performance of electronic devices based on carbon nanotubes is limited by the Schottky energy barrier which the electrons must cross from the metal onto the semiconducting nanotube. The electrical conductivity, , is a measure of how easily electrons are able to £ow through a material. In metals, ¼ en; ð1Þ where e is the charge, n is the electron concentration (number of electrons per unit volume), and is known as the carrier mobility. The carrier mobility is the factor in that takes into account the scattering e¡ects mentioned. The sp2 carbon bonds in the nanotube lattice give the electrons (electrons that contribute to conduction) a large mobility, but it is only the ‘‘armchair’’ tubes [designated by chiral vector indices (n,n) or chiral angle = 30 6 ] that have a large carrier concentration, making it a good electrical conductor and thus metallic in nature. This metallic behavior is clearly seen by the band structure diagram in Fig. 1, in which the valence and conduction bands intersect through the Fermi energy approximately one third of the distance to the ¢rst Brillouin zone edge.9 Conversely, ‘‘zigzag’’ [indices (n,0) or angle = 0 6 ] or other chiral nanotubes have medium to small band gaps, making them semiconducting to semimetallic. An interesting aspect of MWNTs is that the individual shells of a given tube can have di¡erent chiralities. So, a single MWNT can have both metallic and semiconducting layers. Upon multiple measurements of bundles of MWNTs prepared using the arc discharge method, the average has been estimated to be 1000^2000 S/cm.10 Since the electrical conductivity is equal to the reciprocal of the electrical resistivity, (i.e., =1/), is often determined experimentally in nanotubes through measurements of the temperature dependence of by using the standard four-probe geometry. (Note : In many cases, measurements of can be challenging because of

264 Chap. 3.3 POSITES

THERMAL PROPERTIES OF NANOMATERIALS AND NANOCOM-

FIGURE 2 Normalized ðT Þ data to room temperature value for pristine and sintered SWNT ¢lms.11

its dependence on sample dimensions. Because samples are often prepared by pressing nanotube material into mats or random arrays of nanotubes, de¢ning quantities such as cross-sectional area and thickness can be quite di⁄cult. Therefore, electrical resistance, R, is frequently reported rather than , since R /.) Recalling Matthiessen’s rule, we see that the net resistivity of a solid is due primarily to charge carrier scattering and is given by ¼ L þ R :

ð2Þ

The ¢rst term is resistivity due to scattering by phonons. The second term accounts for any other e¡ects that contribute to the scattering cross section, such as impurities and defects, and is known as the residual resistivity. Figure 2 displays normalized resistivity data collected from thin ¢lms of SWNTs. The samples were synthesized by the laser ablation method.11 Both samples were annealed in vacuum to 1000 C. One was then measured, and the data are labeled as pristine. The other sample was sintered by pressing it between electrodes and passing a high current (200 A/cm2 Þ through it while under vacuum. The pristine sample demonstrates metallic behavior (d/dT > 0) at higher temperature but crosses over to negative d/dT behavior at 180 K. This crossover point varies widely over this temperature from sample to sample. The slope of the sintered data, however, remains negative over all temperatures, arguing in favor of semiconducting or activated hopping behavior. In a separate study similar results were seen for pristine SWNTs in the normalized resistance data with a minimum at 190 K, as shown by Fig. 3.12 Introducing impurity K atoms into the lattice results in a signi¢cant contribution from the second term in Eq. (2) to the measured RðT Þ due to scattering e¡ects. The bottom trace in Fig. 3 shows that K-doping has curbed the sharp upturn in the resistance at low T , and, in fact, the slope remains strongly positive. Another independent set of (T Þ data is shown in Fig. 4.13 This set was taken from samples of puri¢ed SWNTs that have had their hollow interiors ¢lled with C60 molecules. These structures have been nicknamed ‘‘peapods’’ and are often denoted C60 @SWNTs. Interactions between adjacent molecules of C60 as well as between the C60 and the SWNT are believed to play an important role in electron transport in these structures. In Fig. 4 the C60 @SWNTs (¢lled circles) are seen to decrease (i.e. increase ) at lower temperatures, compared to the ‘‘empty’’ SWNTs (open squares). The argument for this behavior is that the C60 molecules form new con-

Sec. 1

NANOMATERIALS

265

FIGURE 3 Normalized four-probe RðT Þ data to room temperature value for pristine and K-doped SWNTs.12 Note the change in sign of the slope of the pristine sample, but the slope of the K-doped sample remains positive.

duction paths that are able to bridge localized defect sites that typically impede electron transport in regular SWNTs at low T . 1.1.2. Thermoelectric Power (TEP) In nanotubes thermoelectric power (or thermopower) measurements are often used for determining the sign of the dominant charge carrier and for probing their sensitivity to gas adsorption. The TEP is temperature dependent; however, this dependence varies for metals and semiconductors. At any given temperature it is the manner in which the charge carriers are transported and scattered that will determine the TEP of the metal or semiconductor. Since in most metals the TEP is sensitive to the curvature of the band structure near the Fermi level through the Mott relation

FIGURE 4 Temperature-dependent data for regular SWNTs and ‘‘peapods’’.13 The ratio for empty ðE Þ and ¢lled (F Þ SWNTs is given in the inset.

266 Chap. 3.3 POSITES

THERMAL PROPERTIES OF NANOMATERIALS AND NANOCOM-

2 k2 T Sd ¼ 3e

@ ln ; @" "¼EF

ð3Þ

it is a good indicator of dominant carrier type. In this expression k is the Boltzmann constant, e is the electron charge, and EF is the Fermi energy. The subscript d indicates that this is the contribution of the di¡usion thermopower to the total TEP, and clearly we see that the TEP is linearly dependent on T . In many TEP measurements a nonlinear dependence is often also observed in a plot of S versus T . This nonlinear dependency is usually attributed to a combination of e¡ects, which include contributions from semiconducting tubes, abrupt variations in the density of states, or phonon drag.14 Phonon drag, denoted Sg , is an additional term in the thermopower,15 and the total TEP in metals can be expressed as Stot;met ¼ Sd þ Sg :

ð4Þ

In semiconductors, the mechanism that determines the TEP is somewhat di¡erent than that of metals. The general expression for the TEP in semiconductors is Eg k Eg Ssem ¼ ; ð5Þ 2eT 2e kT where Eg is the gap energy (also known as the band gap).16 Written in the form of the expression on the far right, we see that Ssem / Eg /kT. In contrast to Sd in metals, the TEP in semiconductors is inversely proportional to T and increases with decreasing temperature. However, the total TEP deviates from this relationship near absolute zero and goes to zero due to its dependence on .16 Whereas in metals the only charge carriers that contribute to are electrons, semiconductors have two types of free carriers^electrons and holes. A hole is simply the absence of an electron in the valence band that behaves like a positively charged electron. If electrons are the dominant charge carriers in a material, then the material is said to be n-type. Conversely, if holes are the dominant carriers, the material is said to be p-type. The total electrical conductivity, tot , of a semiconductor is the sum of the electrical conductivity due to electrons and holes (i.e., tot =e +h , where e and h are given by Eq. (1) and n and account for the corresponding hole concentration p and mobility h , respectively, in h Þ. The total TEP of a semiconductor can be written in terms of its dependences as Se e þ Sh h Stot;sem ¼ ; ð6Þ tot where Se and Sh are the electron and hole di¡usion thermopowers, respectively, of the semiconductor. In many semiconductors one of the two terms in Eq. (6) will dominate and the other will only contribute a small part to the overall TEP. The true control variables in the TEP of a semiconductor will, therefore, be the carrier concentration of the dominant carrier type and the corresponding carrier mobility. For example, an n-type semiconductor will have a negative TEP with a magnitude depending primarily on the electron mobility, which is directly related to the electron energy. The electronic properties of nanotubes are a¡ected greatly by their gas exposure history, chirality, and diameter. The TEP has been observed to be particularly sensitive to such changes. Exposure to oxygen (or air) has been shown to have a dramatic e¡ect on the TEP in nanotubes.1719 In Fig. 5a the TEP is plotted as a

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b.

FIGURE 5 (a) TEP ðSÞ versus time data for a SWNT ¢lm cycled between vacuum (S < 0) and O2 saturation (S > 0).17 (b) The T -dependent TEP data for a SWNT ¢lm that has been O2 saturated and then deoxygenated.18

function of time as samples of puri¢ed SWNTs were cycled between vacuum and O2 .17 The temperature was held constant at 350 K during this experiment. The sign of the TEP goes reversibly from positive to negative in a time frame of 15^20 min. as O2 is removed and then reintroduced into the system. The magnitude of the TEP swings from +20 V/K in the presence of O2 to 12 V/K in vacuum. The sign reversal in the TEP is indicative of a change in the dominant charge carrier switching from n-type (in vacuum) to p-type (in O2 Þ. A separate study showed that as T decreases the saturation time due to O2 adsorption increases, going from an order of minutes at T = 350 K to several days at T = 300 K and even longer for T < 300 K.18 Their TEP versus T data also clearly demonstrate the result of oxygen exposure as shown in Fig. 5b. Here TEP data for a ¢lm of puri¢ed SWNTs in its O2 saturated state as well as after being completely deoxygenated is given. Both curves approach zero as T ! 0 and have roughly similar values of magnitude at room temperature but are opposite in sign. Another independent study also displays the role of O2 adsorption on nanotubes as well as the e¡ect of exposure to various other gases.19 Interestingly, they reported that collisions between gas particles and the nanotube wall can have a signi¢cant

FIGURE 6 TEP versus time data for a SWNT mat at T = 500 K. The sample was initially air saturated. It was then degassed and cycled between N2 and He (dark symbols) and vacuum (open symbols).19

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a.

b. (a)

(b)

FIGURE 7 The T dependence of (a) TEP and (b) normalized R for SWNT mats. The letters marking each trace in both ¢gures (A, B, E, I) correspond with the letters in Fig. 6 that signify the condition of the samples when they were measured. Values in parentheses indicate the amount of vertical shift in each trace.19

impact on the TEP. Figure 6 shows the time evolution of the TEP for a mat of asprepared SWNTs as it was exposed to a number of di¡erent environments at T = 500 K after it had ¢rst been air saturated. The air saturated SWNTs show an initial TEP value of +54 V/K. As the sample chamber was evacuated to 106 Torr, the TEP is seen to switch signs and then eventually £atten out over a period of 15 to a degassed (or deoxygenated) value of -44 V/K. The behavior of the TEP upon repeated cycling of the sample between N2 /vacuum and He/vacuum is shown in the ¢gure. A peak corresponding with the presence of each gas can be observed in the TEP data. The time needed to remove the O2 was much longer than the time it took to rid the system of N2 or He. This fact is attributed to a stronger binding between O2 and the walls of the SWNTs, suggesting an exchange of electrons between the two (i.e., chemisorption). The TEP and corresponding normalized R data of the SWNT sample used in Fig. 6 are given in Fig. 7 as a function of T . The letters correspond with those in Fig. 6, signifying the particular environment of the sample chamber during the measurement. Note that each of the TEP plots in Fig. 7a demonstrates a linear T dependence, with the exception of the air-saturated trace, which appears to have a peak at 100 K, giving support for the dominance of the contribution to the thermopower from metallic tubes. Recognizing that each of the normalized R traces have been upshifted by the number indicated in parentheses and, in fact, nearly lie on top of each other, a comparison of Figs. a and b clearly shows that the TEP is a much more sensitive and reliable measurement than R for probing the e¡ects of gas adsorption in nanotubes. The n-type nature of the TEP in pristine or degassed SWNTs is believed to arise from the asymmetry in the band structure in metallic tubes brought about by tube^tube interactions20 or lattice defects.21 There has also been evidence for the existence of the Kondo e¡ect through TEP measurements of SWNTs.22 The TEP (T Þ data for as-prepared SWNT mats that were synthesized with a variety of catalyst particles are given in Fig. 8. The broad peak in the temperature range of 70^100 K has been attributed to the occurrence of magnetic impurities in the SWNTs. This peak is often reported in SWNTs and is typically associated with the Kondo e¡ect. The position and size of the peak depend on the type of catalyst particle used. Each of the traces from SWNTs obtained from Fe^Y, Co^Y, Ni^Y, or Ni^Co catalysts exhibit noticeable Kondo peaks (the Fe^Y being the most signi¢cant at 80 V/K at 80 K). On the other

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FIGURE 8 TEP versus T data for SWNTs synthesized using assorted catalyst particles.22 The broad Kondo peak is evidenced in the upper four traces.

hand, the ones from Mn^Y and Cr^Y do not. Also, by treating the samples that do display a Kondo peak with iodine, we can virtually eliminate this behavior, making the TEP completely linear in T . The e¡ect of ¢lling a SWNT with C60 molecules on the TEP is also worthy of discussion. One study comparing puri¢ed regular SWNTs with C 60 @SWNTs showed a marked decrease in the TEP as a function of T for C60 @SWNTs.13 The regular SWNTs show a room temperature TEP value of 60 V/K after air saturation, whereas the C60 @SWNTs saturate at 40 V/K at 300 K. This is argued as evidence for a signi¢cant phonon drag contribution to the thermopower in pristine SWNTs, since the presence of C60 inside C60 @SWNTs increases the probability for phonon scattering and thus decreases the phonon relaxation time. This e¡ectively reduces the response of the TEP because Sg is directly proportional to the phonon relaxation time. Also, the interior of an empty SWNT is available for oxygen adsorption, while C60 blocks the inner adsorption sites in a ¢lled C60 @SWNT. Both of these factors are thought to play a key role in determining the TEP in C60 @SWNTs. Since much of the previous discussion in this section has been on SWNTs, a general comparison between the TEP(T Þ of SWNTs and MWNTs should prove quite useful (cf. Fig. 9).23 Plots of the T dependence of the TEP for four di¡erent carbon samples are given in Fig. 9, which include data from as-prepared SWNTs produced by the arc discharge (solid circles) and the laser ablation (open boxes) techniques, as well as an as-prepared ¢lm of MWNTs grown by CVD (open diamonds) and a sample of highly oriented pyrolytic graphite (HOPG). All four samples were exposed to room air and room light for an extended period of time and are, therefore, considered to be su⁄ciently O2 -doped. Clearly, SWNTs have a much higher room temperature TEP value (+40 and +45 V/K) than the MWNTs (+17 V/K). Notice that the sign of the TEP of both the SWNTs and the MWNTs is positive, indicating p-type behavior in oxygen^doped nanotubes. The bulk graphite displays a room temperature value of 4 V/K. This ¢gure serves as a quick reference guide for TEP(T Þ values in all three air-exposed carbon forms. Finally, recent advances in mesoscopic thermoelectric measuring devices have made measuring single nanotubes possible.24 Most TEP measurements to date have been made on a collection of SWNTs or MWNTs in the form of mats or

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FIGURE 9 TEP versus T data for air-saturated SWNTs, MWNTs, and highly oriented pyrolytic graphite (HOPG).23

FIGURE 10 SEM image and schematic of novel mesoscopic device used for measuring TEP in individual nanotubes.24

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thin ¢lms and are thus not necessarily intrinsic to an individual tube. Figure 10 displays a SEM image and the schematic of a device currently being used to measure the TEP of isolated nanotubes. The CVD process is used to grow an isolated nanotube on a silicon oxide/silicon substrate. Contact electrodes are then formed on the nanotube by electron-beam lithography. A microheater near one end of the nanotubes is used to establish a temperature gradient of 0.1^0.5 K/m. The thermoelectric voltage is then measured from the electrode contacts using a highinput-impedance voltage preampli¢er. Measurements of this kind have indicated that individual nanotubes are capable of TEP values >200 V/K at T < 30 K. This type of technology should be able to provide valuable insight into the inherent thermoelectric properties of individual nanotubes and opens the door for a variety of di¡erent studies. 1.1.3. Thermal Conductivity, Thermal conductivity, , is simply a measure of the ease with which heat energy can be transferred through a material. It is a material-dependent property and is de¢ned as the constant of proportionality relating the rate of heat £ux, jQ (i.e., heat energy per unit area per unit time), through a solid to the temperature gradient across it: T jQ ¼ : ð7Þ x An expression that relates to the phonon mean free path, , and the heat capacity per unit volume, C, can be derived through the standard kinetic theory of gases and is 1 ¼ Cv‘; ð8Þ 3 where v is the phonon velocity. Early work done in CNTs predicted thermal conductivities that exceeded those seen in either diamond or graphite (two materials with largest known ).25 Some of the ¢rst measurements in low-density mats of asprepared SWNT bundles produced a room temperature of 0.7 W/m-K.26 The (T Þ data for this sample are shown in Fig. 11 over a temperature range of 8^350 K. The data exhibit very close to linear behavior over all T with a slight upturn in d/dT around 25 to 40 K. The low-temperature (<25 K) data shown in the inset are quite clearly linear in T . Calculations of the Lorenz ratio (/T) indicated that the electron contribution to is very small, and therefore only phonon contributions were used to ¢t the data. Since their model agrees well with general behavior of the measured data, the authors argue that phonons dominate over all T due to the one-dimensionality of the SWNTs [i.e., phonon^phonon scattering (umklapp processes) is reduced at high T in a 1D system]. Later measurements performed on high-density, thick ¢lms (5 m) of annealed SWNT bundles after being aligned in a high magnetic ¢eld (HÞ showed a signi¢cant increase in :27 Also, the anisotropic nature of in SWNTs is clearly evidenced by the data in Fig. 12, where measurements have been made parallel to the direction of H-alignment. Here increases smoothly with T in both traces, but the room temperature value is an order of magnitude greater in aligned SWNTs (220 W/ m-K), compared to unaligned (30 W/m-K). This experimental value for in aligned tubes is within an order of magnitude of what is observed in graphite or even diamond.

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FIGURE 11 (T) data for a mat of SWNT bundles.26 The low-temperature behavior is given in the inset.

Theory predicts extraordinarily large values of for isolated nanotubes. Room temperature values of 6600 W/m-K have been calculated for an individual metallic (10,10) armchair nanotubes28 which is nearly twice as much as the 3320 W/m-K that has been reported in diamond.29 But much like the TEP, most measurements have been made in bulk samples of nanotubes in the form of mats or ¢lms, making it di⁄cult to be certain of the intrinsic value of the individual tubes. However, recent developments in microscale devices for the purpose of thermal measurements have made it possible to measure the of a single MWNT.30 Figure 13 gives the T dependence of for a MWNT with diameter 14 nm. The behavior is very similar to that in Fig. 12 for a SWNT mat, with the exception of the downturn near T = 325 K. The most notable feature though, is the large room temperature value of 3000 W/m-K which is greater than that of the SWNTs in Fig. 12 by an order of magnitude but akin to the predicted value for an individual SWNT mentioned earlier.

FIGURE 12 Anisotropic nature ðT Þ of dense SWNT mats.27 The ‘‘aligned’’ sample was done with a high magnetic ¢eld.

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FIGURE 13 The T dependence of for an individual MWNT of diameter 14 nm.30

The reported of C60 @SWNT ‘‘peapod’’ structures is also of interest.13 One might expect that C60 molecules inside the hollow lattice of a SWNT host would act like ‘‘rattlers.’’ In the presence of bulk materials, rattlers can have the e¡ect of reducing the thermal conductivity and thereby enhancing the ¢gure of merit, ZT=S 2 T/ (ZT is a dimensionless value that essentially measures a material’s e¡ectiveness as a thermoelectric). However, this may not necessarily be the case in a 1D system such as a nanotube. The (T Þ data for air-exposed empty and C60 ¢lled SWNT bundles are given in Fig. 14. The general behavior as a function of T is again very similar to that observed in Fig. 12, but interestingly, the C60 @SWNTs show very little variation in (T Þ, and the change that is observed is actually a slight increase in (T Þ. The authors’ argument for this result is threefold : (a) the one vibrational mode that could contribute to produces a negligible sound velocity compared to that which originates from the LA mode of the tube; (b) the interaction forces between the C60 and the tube are not su⁄cient to a¡ect the tube sti¡ness by a sizable amount ; and (c) is reduced by localized e¡ects generated by

FIGURE 14 ðT Þ data comparing empty SWNTs to C60 @SWNTs.13

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shifts in the C60 molecules. Consequently, the presence of C60 inside a nanotube does not substantially alter . 1.1.4. Heat Capacity, C The heat capacity, C, of a solid is de¢ned by the temperature derivative of the energy, U : @U C ¼ ; ð9Þ @T where the subscript indicates the parameter being held constant (i.e., volume or pressure). Usually, volume is held constant for theoretical discussions, but most measurements are made at constant pressure. At low temperatures it can yield important information on phonon and electron behavior and system dimensionality. In many solids the total heat capacity at constant volume (CV Þ is made up of a phonon term and an electron term: ð10Þ CV ¼ Cph þ Cel : Calculations indicate that contributions due to phonons should dominate CV over all T in nanotubes.31 From the Debye approximation at low T , Cph should scale as T raised to the dimensionality of the system (i.e., Cph / T n , where n is the dimension of the system). Theory has shown that a 2D sheet of graphene indeed scales as T 2 ; however, when this sheet is rolled into a seamless cylinder (i.e., a SWNT), Cph / T at su⁄ciently small radius.31 The result is suggestive of the quasi-1D nature of nanotubes since the Cph behavior will cross over to 2D if the radius is larger than allowable for a given value of T . This inverse relationship between the radius and temperature on Cph can be seen in Fig. 15.31 The temperature at which Cph (and CV by virtue of the dominance of the contribution due to phonons) scales as T will increase with decreasing radius in SWNTs. In MWNTs it is the number of shells as well as the radius that determines this behavior. As the number of walls and radii increase, CV is expected to scale between T 2 and T 3 , much closer to that of three-dimensional graphite. Measurements of the heat capacity at constant pressure (CP Þ for bundles of puri¢ed SWNTs plotted as the speci¢c heat (=CP /mass) are shown in Fig. 16.32 The CP ðT Þ data in Fig. 16a show the behavior of CP from 2^300 K. Figure 16b

FIGURE 15 Schematic demonstrating the relationship between the radius (R), T , and Cph in SWNTs.31 For su⁄ciently small R and T ; Cph scales as T ; otherwise it scales as T 2 .

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a.

b.

(a)

(b)

FIGURE 16 The T dependence of CP per unit mass for SWNT bundles.32 (a) The cooling data from room temperature to 2 K and (b) the low-T data showing the e¡ects of He exposure on CP .

FIG. 17 Upon subtracting the T 2 term, CP in bundles of SWNTs is seen to be the addition of a T 0:62 term and a T 3 term from 0.3^4 K.34

displays the low-temperature (<25 K) data. The presence of He is seen here to have the e¡ect of increasing CP at low T (triangles). This result is in good agreement with the theory, which predicts this rise in CP upon adsorption of He into the interstitial channels of the SWNT bundles.33 A log^log plot of the data in Fig. 16a (not shown here) was in very good agreement with that modeled from an individual SWNT down to 4 K, demonstrating the 1D nature of the samples.32 Finally, more recent measurements of CP down to 0.1 K show that the heat capacity is determined by three terms with di¡erent powers of T in samples of puri¢ed SWNT bundles. 34 Their data ¢t very well with the relation CP = T 2 +T0:62 +T3 over 0.3^4 K. The T 2 term is attributed to ferromagnetic catalyst particles in the sample. Upon accounting for this contribution, the data are

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seen to be in reasonable agreement with the remaining two terms, as shown by Fig. 17. The source of the T 0:62 term is not explicitly understood by the authors, however, the T 3 term is said to originate from the tube^tube coupling within the SWNT bundles, thereby giving rise to the 3D behavior at low T . 1.2. Nanowires Whereas carbon nanotubes are hollow graphene cylinders with large aspect ratios, nanowires are solid cylinders with dimensions of the same order as nanotubes (nanowires of shorter lengths having aspect ratios of 10 are typically referred to as nanorods) and come in a wide variety of di¡erent materials. Several techniques have been developed for nanowire synthesis. These include the template method in which tiny pores in a chemically stable material are ¢lled by one of an assortment of processes (e.g., vapor deposition, electrochemical deposition, pressure injection, etc.) with the desired material of the nanowires, the vapor^liquid^ solid (VLS) method that uses the supersaturation of a liquid catalyst particle by gaseous material to precipitate a solid in one direction, and the solution phase growth of nanowires through the use of surfactants. Some types of nanowires that have been synthesized with these methods include Bi, Bi2 Te3 , BN, CdS, Cu, Fe, GaAs, GaN, Ga2 O3 , GaP, GaS, Ge, In, InP, InAs, MgO, Si, SiGe, SiO2 , Sn, SnO2 , and ZnO. For a review on these and other techniques as well as the many more types of nanowires that have been studied to date, see Ref. 8. Because, like nanotubes, they can often be thought of as 1D systems, nanowires demonstrate very unique properties compared to their bulk counterparts and show great potential for nanoscale devices. 1.2.1. Electrical Conductivity The diameter size in nanowires is perhaps the most signi¢cant parameter in electrical conduction. Electrical transport is expected to be comparable to that of bulk material except when the diameter becomes small enough (on the order of the electron wavelength).8 In this case 1D quantum size e¡ects can be expected. As in nanotubes, electron transport in nanowires is expected to be primarily di¡usive, except for extremely short wire segments. Measurements in some semiconducting nanowires have exhibited particularly unique properties. Silicon nanowires, one of the most extensively studied types of nanowires, have shown an increase from 45 to 800 nS in the average room temperature transconductance, with a peak value of 2000 nS across a single nanowire with a diameter of 10^20 nm and a length of 800^2000 nm after treatment to reduce the e¡ects of oxidation.35 In accordance with Eq. (1), they also showed an increase in the average from 30 to 560 cm2 /V-s, with a peak value of 1350 cm2 /V-s. Both results are improvements on what is seen in planar silicon. Another study found that GaN nanowires (diameter 30 nm; length 330 nm) had an average value of = 2.15 cm2 /V-s at room temperature, compared to 380 cm2 /V-s found in bulk GaN.36 Measurements of the T dependence of R can also show the dramatic contrast between nanowires and their bulk parents. For example, Fig. 18 clearly shows the di¡erence in the RðT Þ data for bulk Bi and Bi nanowires of various diameters.37 Bismuth nanowires were calculated to crossover from semimetallic to semiconducting behavior at a diameter of 50 nm due to the e¡ects of quantum con¢nement.38

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FIGURE 18 Normalized resistance RðT Þ data for bulk Bi and several Bi nanowires of assorted diameters.37

The experiments in Fig. 18 con¢rmed this prediction by showing a transition at 48 nm. This crossover e¡ect is purely a result of the extremely small size of the Bi nanowires and cannot be observed in its bulk form. 1.2.2. Thermoelectric Power Thermoelectric measurements in certain types of nanowires demonstrate the distinct

b.

a.

(a)

(b)

FIGURE 19 T dependence of the TEP comparing bulk and nanowire samples of (a) Bi39 and (b) Zn.8;40

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advantages of being extremely small as well. The TEP data in Fig. 19 present clear evidence of this. Figure 19a shows the SðT Þ data for bulk Bi and Bi nanowires as well as Bi nanowires alloyed with Sb (5 at.%).39 The magnitude of the TEP over all T is increased by Sb alloying. Also, in both the Bi and Bi0:95 Sb0:05 nanowires a decrease in diameter corresponds to an increase in TEP magnitude. Each of the four nanowire samples shows an enhanced room temperature value, but only the Bi0:95 Sb0:05 nanowire with a diameter of 45 nm is greater over the entire range of T . A comparison of the measured TEP in bulk Zn and samples of Al2 O3 and Vycor glass with Zn nanowires embedded is given in Fig. 19b.8;40 Both samples containing Zn nanowires exhibit enhancements in the TEP with respect to the bulk sample. However, the smaller-diameter Zn nanowire (4 nm) samples show a huge increase in TEP magnitude, in particular at T = 300 K. 1.2.3. Thermal Conductivity and Heat Capacity Very little has been reported to date on the intrinsic thermal conductivity and heat capacity in nanowires, due to the di⁄culty of these types of measurements. Measurements show a strong dependence on diameter and surface oxidation.8 Some (T Þ data have shown that Si nanowires (diameter 22 nm) scale as T . Indicative of their 1D nature, the CðT Þ data were linear in T as well. 1.3. Nanoparticles Nanoparticles can be thought of as zero-dimensional (i.e., constrained in all three directions) ¢ne particles usually containing 10 to 1000 atoms.1 They are sometimes referred to as nanoclusters. They can be made of virtually any kind of material. An understanding of their thermal properties is important for their use in the development of nanoscale devices. For example, the use of thin ¢lms and coatings of nanodiamond clusters in order to take advantage of the large thermal conductivity of diamond shows promise in a variety of thermal management applications.

FIGURE 20 data for ‘‘nano£uids’’ consisting of ethylene glycol and Cu nanoparticles normalized to the of regular ethylene glycol.41

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Nanoparticles have been reported to enhance the thermal conductivity in certain £uids. Figure 20 shows the versus nanoparticle concentration data for samples of ethylene glycol containing Cu nanoparticles normalized to regular ethylene glycol.41 Each of these ‘‘nano£uids’’ exhibits improvements in data. The most signi¢cant increase in (40%) can be seen in the sample containing 0.3 vol.% Cu nanoparticles and thioglycolic acid (triangles), which was used to stabilize the nanoparticles. The average diameter of the nanoparticles was less than 10 nm. Note that the enhancement in appears to be time dependent, as evidenced by the decrease in for the ‘‘old’’ samples (2 months) as compared to the ‘‘fresh’’ ones (2 days). The authors do not specify the cause of this behavior, and it is believed that further investigations are needed for a more thorough understanding of this phenomenon. Most of the work reported on the thermal properties of nanoparticles has been in the area of heat capacity. Calculations predict that C in nanoparticles, due to their tiny size, will not follow Debye’s T 3 law seen in most solids at low temperatures but an exponential behavior in T and particle size.42 However, measurements in certain ferromagnetic nanoparticles like MnFe2 O4 do show a T 3 dependence with the contribution of an additional T 3=2 magnetic term.43 The CP ðT Þ data from 2 to 300 K are given for a sample of MnFe2 O4 nanoparticles in Fig. 21. The data increase with temperature over all T but show a de¢nite change at T = 19 K. For T < 19 K, the data (not show here) do indeed ¢t well an expression for C consisting of T 3 and T 3=2 terms. 2. NANOCOMPOSITES In this chapter we refer to nanocomposites as materials that have any of the previously mentioned nanostructures embedded in them. These types of materials have generated a lot of interest, since it is believed that the incorporation of certain nanosized structures can enhance the host material’s various physical and chemical properties and, of particular interest, their thermal properties.

FIGURE 21 CðT Þ data for a sample of MnFe2 O4 nanoparticles.43 The arrow indicates a sharp change in the data at T = 19 K.

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a.

b.

FIGURE 22 Enhancements in seen in many nanotube/polymer composites is evidenced by data in ¢lms of both (a) P3OT and SWNTs45 and (b) PANI and MWNTs.46

2.1. Electrical Conductivity Enhancements in have been reported in a number of materials that include nanostructures in their composition, speci¢cally nanotube/polymer composites.4446 The data as a function of SWNT content (wt.%) in ¢lms (thickness 100 nm) of poly(3-octylthiophene) (P3OT) and SWNTs is shown in Fig. 22a.45 An increase in at room temperature by nearly ¢ve orders of magnitude can be seen as the SWNT concentration is increased from 0 to 35 wt.%. A particularly sharp change occurs as the amount of SWNTs increased from 12 to 20 wt.%. A signi¢cant change in was also seen in ¢lms (thickness 20 m) of polyaniline (PANI) and MWNTs.46 The table in Fig. 22b shows several measured quantities of the PANI/MWNT nanocomposites, including the room temperature . The ¢rst column in this table corresponds to the MWNT concentration in the ¢lm: P-1 = 0 wt.%, P-2 = 0.5 wt.%, P3 = 1.0 wt.%, and P-4 = 5 wt.%. Both the 1 and 5 wt.% samples show an increase in , compared to ¢lms without MWNTs. It has also been reported that assorted metal-oxide composites change from insulating to conducting upon evenly dispersing carbon nanotubes throughout the sample.47 2.2. Thermal Conductivity The incorporation of carbon nanotubes into various materials can also have the e¡ect of improving thermal conductivity. The (T Þ data in Fig. 23 show a comparison between samples of industrial epoxy with and without bundles of SWNTs mixed into the composite.48 The epoxy with SWNTs (1 wt.%) displays an increase in over the entire range of T . Most notably, the room temperature value of the SWNT epoxy exhibits an enhancement of 125%. This gives clear evidence of the advantages in thermal management that can be attained by simply adding carbon nanotubes to the given material. 3. APPLICATIONS We close this chapter with a brief discussion of burgeoning applications of nanomaterials and nanocomposites which have demonstrated extraordinary potential due to their exceptional properties. However, due to the nature of this chapter,

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FIGURE 23 ðT Þ data for pristine epoxy and SWNT-epoxy nanocomposite.48

this discussion will be restricted to only a couple of applications involving thermal properties. One of the most recently reported applications for nanotubes is their use as a ‘‘nanothermometer.’’49 Liquid Ga was seen to expand linearly with T over a range of 50^500 C when placed inside a nanotube (diameter 75 nm and length 10 m). The electron microscope images in Fig. 24a^c display the Ga menisci at 58 C, 490 C, and 45 C, respectively. In Fig. 24d the reproducibility and precision of the measurements are demonstrated by the height of the meniscus versus T data. A second application that has shown a lot of promise is the use of nanotubes as gas sensors. As discussed earlier, the TEP in nanotubes is extremely sensitive to gas exposure. Based upon this fact the thermoelectric ‘‘nano-nose’’ was developed.50 By using isothermal Nordheim^Gorter (S vs. ) plots like those in Fig. 25a, the adsorption of various gases as well as the particular adsorption mechanism (i.e., physisorption or chemisorption) can be detected. In Fig. 25a the linear behavior of H2 , He, and N2 is indicative of physisorption of these gases onto the various nanotube surfaces. On the other hand, the nonlinear response of NH3 and O2 shown in the inset signi¢es electron transfer between the gas molecules and the nanotube (i.e., chemisorption). Figure 25b displays the T dependence of the TEP for a puri¢ed SWNT mat after being degassed (S0 Þ and then after being exposed to

FIGURE 24 Images of the linearly varying Ga meniscus at (a) 58o C, (b) 490o C, and (c) 45o C inside a carbon nanotube.49 The scale bar in (a) corresponds to 75 nm. (d) Reproducibility established by the height versus T plot of the meniscus for both warming and cooling cycles.

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(a) a.

THERMAL PROPERTIES OF NANOMATERIALS AND NANOCOM-

b.

(b)

FIGURE 25 (a) Nordheim^Gorter (S vs. ) plots demonstrating the senstitivity of nanotubes to exposure to various gases as well as indicating the type of adsorption process involved.50 (b) SðT Þ data for a degassed SWNT mat and as it was exposed to di¡erent hydrocarbon vapors.51

di¡erent hydrocarbon vapors (n = 3^5).51 After each measurement the sample was degassed until it reached its initial value. As clearly seen in the ¢gure, exposure to each hydrocarbon vapor renders a di¡erent SðT Þ signature. The results from both of these studies demonstrate the potential for using nanotubes as highly sensitive gas sensors. As these types of techniques and di¡erent technologies continue to progress, the pace to exploit these nanomaterials appears to quicken, and the list of their possible uses seems to grow exponentially. 4. REFERENCES C. Kittel Introduction to Solid State Physics,7th ed., (Wiley, New York 1996), p. 168^169. S. Iijima Helical Microtubules of Graphitic Carbon Nature 354, 56 (1991). C. Journet, L. Alvarez, V. Micholet, T. Guillard, M. Lamy De La Chapelle, E. Anglaret, J. L. Sauvajol, S. Lefrant, P. Bernier, D. Laplaze, G. Flamant, and A. Loiseau Single Wall Carbon Nanotubes: Two Ways of Production Syn. Met. 103, 2488 (1999). 4. A. Thess, R. Lee, P. Nicolaev, H. Dai, P. Petit, J. Robert, C. Xu, Y. H. Lee, S. G. Kim, A. G. Rinzler, D. T. Colbert, G. E. Scuseria, D. Tomanek, J. E. Fischer, and R. E. Smalley Crystalline Ropes of Metallic Carbon Nanotubes Science 273, 483 (1996). 5. H. M. Cheng, F. Li, X. Sun, S. D. M. Brown, M. A. Pimenta, A. Marucci, G. Dresselhaus, and M. S. Dresselhaus Bulk Morphology and Diameter Distribution of Single-Walled Carbon Nanotubes Synthesized by Catalytic Decomposition of Hydrocarbons Chem. Phys. Lett. 289, 602 (1998). 6. R. Saito, M. S. Dresselhaus, and G. Dresselhaus Physical Properties of Carbon Nanotubes (World Science, 1998). 7. M. S. Dresselhaus, G. Dresselhaus, and R. Saito C60 -Related Tubules Solid State Comm. 84, 201 (1992). 8. M. S. Dresselhaus, Y.-M. Lin, O. Rabin, M. R. Black, and G. Dresselhaus Nanowires, Springer Handboek of Nanotechnology, edited by Bharat Bhushan, Springer-Verlag Heidelberg, Germany, 99-145 (2004). 9. D. T. Colbert and R. E. Smalley Fullerene Nanotubes for Molecular Electronics Trends In Biotech. 17, 46 (1999). 10. K. Kaneto, M. Tsuruta, G. Sakai, W. Y. Cho, and Y. Ando Electrical Conductivities of MultiWall Carbon Nanotubes, Synth. Met. 103, 2543 (1999). 1. 2. 3.

Sec. 4

REFERENCES

283

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284 Chap. 3.3 POSITES

THERMAL PROPERTIES OF NANOMATERIALS AND NANOCOM-

39. Y.-M. Lin, O. Rabin, S. B. Cronin, J. Y. Ying, and M. S. Dresselhaus Semimetal-Semiconductor Transition in Bi1 x Sbx Alloy Nanowires and Their Thermoelectric Properties Appl. Phys. Lett. 81(13), 2403 (2002). 40. J. P. Heremans, C. M. Thrush, D. T. Morelli, and M.-C. Wu Thermoelectric Power of Bismuth Nanocomposites Phys. Rev. Lett. 88, 216801-1 (2002). 41. J. A. Eastman, S. U. S. Choi, S. Li, W. Yu, and L. J. Thompson Anomalously Increased E¡ective Thermal Conductivities of Ethylene Glycol-Based Nano£uids Containing Copper Nanoparticles Appl. Phys. Lett. 78(6), 718 (2001). 42. K. N. Shrivastava Speci¢c Heat of Nanocrystals Nano Lett. 2(1), 21 (2002). 43. G. Balaji, N. S. Gajbhiye, G. Wilde, and J. Weissmu«ller Magnetic Properties of MnFe2 O4 Nanoparticles J. Magnetism and Magnetic Mat. 242-245, 617 (2002). 44. J. M. Benoit, B. Corraze, S. Lefrant, W. J. Blau, P. Bernier, and O. Chauvet Transport Properties of PMMA-Carbon Nanotubes Composites Syn. Met. 121, 1215 (2001). 45. E. Kymakis, I. Alexandou, and G. A. J. Amaratunga Single-Walled Carbon Nanotube-Polymer Composites: Electrical, Optical and Structural Investigation Syn. Met. 127, 59 (2002). 46. P. C. Ramamurthy, W. R. Harrell, R. V. Gregory, B. Sadanadan, and A. M. Rao Electronic Properties of Polyaniline/Carbon Nanotube Composites Syn. Met. 137, 1497 (2003). 47. E. Flahaut, A. Peigney, Ch. Laurent, Ch. Marlie're, F. Chastel, and A. Rousset Carbon Nanotube-Metal-Oxide Nanocomposites: Microstructure, Electrical Conductivity and Mechanical Properties Acta Mater. 48, 3803 (2000). 48. M. J. Biercuk, M. C. Llagune, M. Radosavljevic, J. K. Hyun, A. T. Johnson, and J. E. Fischer Carbon Nanotube Composites for Thermal Management Appl. Phys. Lett. 80(15), 2767 (2002). 49. Y. Gao and Y. Bando Carbon Nanothermometer Containing Gallium Nature 415, 599 (2002). 50. C. K. W. Adu, G. U. Sumanasekera, B. K. Pradhan, H. E. Romero, and P. C. Eklund Carbon Nanotubes: A Thermoelectric Nano-Nose Chem. Phys. Lett. 337, 31 (2001). 51. G. U. Sumanasekera, B. K. Pradhan, H. E. Romero, K. W. Adu, and P. C. Eklund Giant Thermopower E¡ects from Molecular Physisorption on Carbon Nanotubes Phys. Rev. Lett. 89(16), 166801-1 (2002).

INDEX Absolute technique : see Steady-state thermal conductivity technique AlCuFe quasicrystals, 256, 257 n-Alkanes, 98^99 Alloys, 86^87 AlPdMn quasicrystals, 256^258 Alumina (Al2 O3 Þ, 244, 245 Aluminum nitride (AIN), 240^243 diamond ¢lm on, 244 Amorphous silicon dioxide (a-SiO 2 Þ, 171^172 Annealing, 142 Antimony telluride (Sb2 Te3 Þ, 124^12 Atomic displacement parameters (ADPs), 134, 139 Bare substrate specimens, 218^219 Bipolar conduction, 110^112 Bipolar di¡usion, 8 Bismuth and bismuth-antimony alloys, 126^127 Bismuth selenide (Bi2 Se3 Þ, 124^125 Bismuth telluride (Bi2 Te3 Þ, 112^114 and its alloys, 124^126 Bi2 Te3 /Sb2 Te3 superlattices (SLs), 178^ 181 Bloch-Gru«neisen formula, 58 Bloch-Wilson theory, 83^85 Boltzmann equation (BE), 10, 12, 32^35, 43, 95, 162 linearization, 35, 47 Born-Oppenheimer approximation, 52 Boundary scattering, 78 Bridge method, 215, 222^224

Bulk materials, determining thermal conductivity of, 187^188, 202; see also speci¢c topics Callaway model, 12, 16 Carbon-doped silicon dioxide (CDO), 172 Carbon ¢ber-incorporated alumina ceramics, 245 Ceramic composites, 244^245 Ceramic ¢bers, 245 Ceramics, 239, 251 novel materials with various applications, 244^248 rare-earth based, 246^247 thermoelectric, 247^248 traditional materials with high thermal conductivity, 240^244 Chalcogenide glasses, 248^250 Chalcogenides and oxides, novel, 145^ 148 Chemical vapor deposition (CVD), 262 Clathrates, 137^141 Collisions, 24 Comparative technique, 193^195 Copper (CU) thin ¢lms, 169, 170 Crystalline insulators : see under Insulators Crystals, 100; see also Quasicrystals boundary scattering, 117^118 phonon scattering by impurities, 115^ 117 phonon scattering in pure, 114^115

286

CsBi4 Te6 , 147 Current density : see Electric current density Debye approximation, 11^12, 94, 135^137 Debye equation of state, 119 Debye frequency, 51 Debye model for phonon distribution, 118 of thermal conductivity of solids, 100 Debye temperature, 81, 119 Debye theory, 11 Debye’s equation for heat transfer in gases, 94 Diamond, impurities in, 97 Diamond ¢lms, 174 on aluminum nitride, 244 Dielectric ¢lms, 171, 174 amorphous SiO2 ¢lms, 171^172 thin ¢lm coatings, 173^174 Di¡usion, bipolar, 8 Di¡usivity method, laser-£ash thermal, 197 Dislocations, 78 Drude formula, 25, 40 Drude model, 24^29 Elastic electron scattering, 42 Electric arc discharge, 262 Electric current density (Je Þ, 24, 35^36 Electrical conductivity (Þ, 40^44 of carbon nanotubes, 262^265 of nanocomposites, 279^280 of nanowires, 276^277 Electrical heating and sensing, 208 cross-plane thermal conductivity measurements of thin ¢lms, 208 steady-state method, 212^214 3! method, 208^213 in-plane thermal conductivity measurements, 214^216 bridge method, 215, 222^224 membrane method, 215^222 without substrate removal, 225 Electrical resistivity, 170; see also Electronic thermal resistivity ; Scattering processes Electron-hole scattering, 68

INDEX

Electron scattering; see also Scattering processes elastic, 42 Electronic thermal conduction, 3^9; see also Lattice thermal conductivity Electronic thermal conductivity, 23, 44^46, 80 Electronic thermal resistivity, 69 ; see also Electrical resistivity Electrons, 24 Fermi-Dirac distribution, 29^30 Fermi energy, 40 Fermi liquid theory, 65, 66 Fermi surfaces, 40^42, 68, 84^85 Film-on-substrate system, 218^219 Fourier law, 26 Friedel sum rule, 50 Fuchs theory, 170 GaAs/A1As superlattices (SLs), 178^ 181 Gas sensors, use of nanotubes as, 281 Germanium, 129, 130 Glass-ceramic superconductor, 245^246 Glasses, 93^94, 239, 248, 250^251 chalcogenide, 248^250 comparison with crystals, 100 detailed models of thermal conductivity, 100^101 recent amorphous ice results, 101 Half-Heusler compounds, 141^142 e¡ect of annealing, 142 e¡ect of grain size reduction, 144^145 isoelectronic alloying on M and Ni sites, 142, 144 Harman technique, 201^202 Heat current density: see Thermal current density Heat £ux, 10 Heat pulse method, 220, 224 Heat spreading e¡ect, methods of measuring, 215, 216 Heat transfer method, 218^219 Heusler alloys, 142; see also Half-Heusler compounds HfNiSn, 142^144 Highly oriented pyrolytic graphite (HOPG), 269, 270

INDEX

Horizontal processes, 46 Ice, 101 crystalline phases of, 98^99 Ideal resistivity, 58 Ideal thermal resistivity, 60, 84 Impurity scattering, 78, 80 Inclusion compounds, 99 Insulators, 93^94 minimal thermal conductivity, 101 phononic thermal conductivity in simple crystalline, 94^97 acoustic phonons carry heat, 94^96 impurities, 97 role of optic modes in more complex, 97^99 molecular, 97^99 optic-acoustic coupling, 99^100 Kapaitza resistance, 154^156, 161 Kinetic theory, simple, 2 Klemens coe⁄cient and numerical solution, 83, 84 Laser-£ash thermal di¡usivity method, 197 Laser vaporization, 262 Lattice thermal conductivity, 9^17, 73 phonon thermal resistivity limited by electrons, 73^77 prediction of, 118^120 in semiconductors, 112^114 Lattice vibrations : see Phonons Lead selenide (PbSe), 128 Lead telluride (PbTe), 127^128 Liouville theorem, 34 Lorenz number (LÞ, 110, 111, 170^171 Lorenz ratio (LÞ, 45, 61, 85^86 Maggi-Righi-Leduc e¡ect, 77 Magnesium silicon nitride (MgSiN2 Þ, 247 ‘Maldonado’ technique, 197^199 Mass-defect scattering, 117 Matthiessen’s rule, 5, 43, 44, 46 Membrane method, 215^222 Metallic thin ¢lms : see under Thin ¢lms Metals, 21, 87^88; see also speci¢c topics carriers of heat in, 22^23

287

Metals (cont.) processes limiting phonon thermal conductivity in, 73^79 pure, 28^29, 79^86 speci¢c heat, 29^32 thermal conductivity of real, 79^87 transport parameters for monovalent, 82^83 Microfabrication techniques, 219 Minimal thermal conductivity, 101 Mirage method, 231 MNiSn, 141^142 Modulation heating techniques, 220^ 221, 224 Molecular dynamics (MD), 163 Mott relation, 265^266 Multiwalled nanotubes (MWNTs), 262, 263, 269, 270, 272, 280 MX3 , 129 NaCo2 O4 , 147^148 Nanocomposites, 261, 279 applications, 280^282 electrical conductivity, 279^280 thermal conductivity, 280 ‘Nano£uids,’ 278^279 Nanomaterials, 261 applications, 280^282 Nanoparticles, 278^279 ‘Nanothermometer,’ 280^281 Nanotubes, carbon, 262 electrical conductivity, 262^265 heat capacity (C), 274^275 thermal conductivity (Þ, 271^273 thermoelectric power (TEP), 265^271 Nanowires, 276 electrical conductivity, 276^277 thermal conductivity and heat capacity, 278 thermoelectric power, 277^278 Non-Kapitzic heat £ow, 161^162 analytic theory, 162^163 Normal processes (N-processes), 12, 115^116 Optic-acoustic coupling, 99^100 Optical-electrical hybrid methods, 232^233

288

Optical heating methods, 225^226 frequency-domain photothermal and photoacoustic methods, 230^232 time-domain pump-and-probe methods, 226^229 Parallel thermal conductance (PTC) technique, 200^201 Partially stabilized zirconia (PSZ), 174 Pauli exclusion principle, 29, 30, 38, 62 Peltier coe⁄cient, 39 Peltier e¡ect, 39 Phonon-boundary scattering rate, 14^16 Phonon-dislocation scattering, 15 Phonon dispersion curves, 9^10 Phonon distribution, Debye model for, 118 Phonon distribution function, 10, 12 Phonon method, dominant, 17 Phonon-phonon normal scattering, 14 Phonon-point-defect scattering, 14 Phonon scattering(s), 14, 16 ; see also under Crystals ; Scattering processes processes, 11^12, 17 relaxation rate, 15^16 Phonon spectrum, contribution to thermal conductivity of di¡erent parts of, 117, 118 Phonons, 9, 156^157 ; see also speci¢c topics acoustic, 94^96 mean free path, 11 Photothermal de£ection method, 231 Photothermal displacement method, 231 Photothermal emission method, 230^231 Photothermal re£ectance method, 230 Photothermal re£ectance signal, 228^229 Photothermoelectric methods, 232^233 Point-defect scattering, 115 Polyaniline (PANI), 280 Polysilicon ¢lms, 175^176 Pulse heating, 220, 224 Pulse-power method, 197^199 Pump-and-probe methods, time-domain, 226^229 Pyrolytic graphite, highly oriented, 269, 270

INDEX

Quasicrystalline materials, 255^256, 259 contributions to thermal conductivity, 257 glasslike plateau in, 258 Quasicrystals low-temperature thermal conduction, 257^258 poor thermal conduction, 258 Radial £ow method, 194^197 Radial methods, classes of apparatus in, 195 Radiation, 102 Radiation loss, 191, 192 Relaxation time, 74, 116; see also under Phonon scattering(s) Relaxation time approximation, 34^35, 42^44, 68 Scattering processes, 46; see also speci¢c topics electron-electron scattering, 61^64 e-e processes and electrical resistivity, 64^69 e-e processes and thermal resistivity, 69^73 electron-phonon scattering, 50^61 impurity scattering, 46^50 Screened Coulomb interaction, 47 Seebeck coe⁄cient (S), 39, 45, 106, 107, 109, 111, 112, 142 Semiconductor lasers, 167^168 Semiconductor superlattices, 178^182 Semiconductors, 105^106, 149; see also Clathrates ; Half-Heusler compounds electronic thermal conductivity in bipolar conduction, 110^112 nondegenerate and degenerate, 109^110 separation of lattice thermal conductivity and, 112^114 transport coe⁄cients for a single band, 106^109 Semimetal thin ¢lms, 174, 176^177 Silicon, 128^129 Silicon carbide ¢ber-reinforced ceramic matrix composite (SiC-CMC), 244^245

INDEX

Silicon dioxide (SiO2 Þ, 171^172, 256 Silicon-germanium (Si-Ge) alloys, 129 Silicon nitride (Si3 N4 Þ, 243^244 Silicon thin ¢lms, 175^177 Silver, 6 Single-walled nanotubes (SWNTs), 262, 264, 267^275, 279^282 Size e¡ects, 168; see also Thin ¢lms Skutterudite thin ¢lms and superlattices, cross-plane thermal conductivity of, 177 Skutterudites, 129^130 binary (un¢lled), 130^131 e¡ect of doping on Co site, 132^133 ¢lled, 133^137 Smith-Palmer equation, 87 Steady-state methods, 212^214, 216^ 220, 223 Steady-state thermal conductivity technique, 188^189 heat loss and thermal contact issues, 189^191 heat loss terms, 191^193 Superlattices (SLs), 153^154, 163^164, 168, 182; see also Semiconductor superlattices parallel to layers, 154 perpendicular to layers, 154 multilayer interference, 156^157 temperature, 157^159 thermal boundary resistance, 154^156 with thick layers, 159^160 semiconductor, 178^182 TAGS-85, 128 Temperature, de¢ning, 157^159 Temperature sensors : see Electrical heating and sensing Thermal barrier coatings (TBCs), 173^174 Thermal conductivity, 1^2, 17 de¢ned, 2 standard formula for, 163 Thermal conductivity coe⁄cient (Þ, 95^97 temperature dependence, 96^97 Thermal conductivity tensor, 94 Thermal current density (JQ Þ, 25^26, 36 Thermal parameters, 134

289

Thermal resistivity ; see also Ideal thermal resistivity; Lattice thermal conductivity; Scattering processes electron-electron (scattering) processes and, 69^73 electronic, 69; see also Electrical resistivity Thermoelectric materials, 123^124, 149; see also speci¢c materials Groups IV and Group IV elements, 127^128 Thermoelectric power (TEP), 39, 265^ 271, 277^278 Thin ¢lm coatings on dielectric ¢lms, 173^174 Thin-¢lm thermal conductivity characterization, techniques for, 205^208, 233^234; see also speci¢c techniques Thin ¢lms, 167^168, 182; see also Dielectric ¢lms ; Electrical heating and sensing metallic, 169^171 semiconductor, 174^177 semimetal, 174, 176^177 Thomas-Fermi screening parameter, 48, 53 Time-domain pump-and-probe methods, 226^229 TiNiSn1x Sbx , 145 TiNiSn0:95 Sb0:05 , 145 Tl2 GeTe5 , 146^147 Tl9 GeTe6 , 146 Tl2 SnTe5 , 146^147 Transient heating methods, 220^222, 224 Transport coe⁄cients, 35^40 Umklapp processes (U-processes), 12, 77^80, 115^116 Vapor deposition, chemical, 262 Vaporization, laser, 262 Vertical processes, 46 Wiedemann-Franz law, 4^7, 23, 27, 39, 46, 86, 88, 106, 257 Yukawa potential, 47^48

290

Z-meters, 201^202 Zr0:5 FH0:5 NiSn, 142^144 ZrNiSn, 142^144

INDEX